Cooperation between reactive oxygen and nitrogen intermediates in killing of Rhodococcus equi by activated macrophages

Rhodococcus equi is a facultative intracellular bacterium of macrophages which can infect immunocompromised humans and young horses. In the present study, we examine the mechanism of host defense against R. equi by using a murine model. We show that bacterial killing is dependent upon the presence of gamma interferon (IFN-gamma), which activates macrophages to produce reactive nitrogen and oxygen intermediates. These two radicals combine to form peroxynitrite (ONOO(-)), which kills R. equi. Mice deficient in the production of either the high-output nitric oxide pathway (iNOS(-/-)) or the oxidative burst (gp91(phox-/-)) are more susceptible to lethal R. equi infection and display higher bacterial burdens in their livers, spleens, and lungs than wild-type mice. These in vivo observations, which implicate both nitric oxide (NO) and superoxide (O(2)(-)) in bacterial killing, were reexamined in cell-free radical-generating assays. In these assays, R. equi remains fully viable following prolonged exposure to high concentrations of either nitric oxide or superoxide, indicating that neither compound is sufficient to mediate bacterial killing. In contrast, brief exposure of bacteria to ONOO(-) efficiently kills virulent R. equi. The intracellular killing of bacteria in vitro by activated macrophages correlated with the production of ONOO(-) in situ. Inhibition of nitric oxide production by activated macrophages by using N(G)-monomethyl-L-arginine blocks their production of ONOO(-) and weakens their ability to control rhodococcal replication. These studies indicate that peroxynitrite mediates the intracellular killing of R. equi by IFN-gamma-activated macrophages.     

Protection of myelin basic protein immunized mice from free-radical mediated inflammatory cell invasion of the central nervous system by the natural peroxynitrite scavenger uric acid

Peroxynitrite (ONOO(-)), the product of nitric oxide (NO(radical)) and superoxide (O(2)(-radical)), is believed to be a major contributor to immunotoxicity when produced by activated cells expressing inducible nitric oxide synthase (iNOS). Uric acid (UA) is a natural scavenger of ONOO(-) that is present at high levels in the sera of humans and other higher order primates relative to most lower mammals. We have previously shown that UA treatment is therapeutic in experimental allergic encephalomyelitis (EAE), a rodent model of multiple sclerosis (MS). In this study we have examined the effect of UA therapy on the dynamics of the appearance of iNOS-positive cells in central nervous system (CNS) tissue of mice subjected to the stimuli that cause EAE. The results indicate that UA prevents activated monocytes from entering CNS tissue where they may contribute to the pathogenesis of MS and other CNS diseases.     

A computational model for free radicals transport in the microcirculation

Nitric oxide (NO), superoxide (O(2)(-)), and peroxynitrite (ONOO(-)) interactions in pathophysiologic conditions such as cardiovascular disease, hypertension, and diabetes have been studied extensively in vivo and in vitro. A reduction in bioavailability of NO is a common event that is known as the endothelial dysfunction in these conditions. Despite intense investigation of NO biotransport and O(2)(-) and ONOO(-) biochemical interactions in vasculature, we have very little quantitative knowledge of distributions and concentrations of NO, O(2)(-), and ONOO(-) under normal physiologic and pathophysiologic conditions. Based on fundamental principles of mass balance, vessel geometry, and reaction kinetics, we developed a mathematical model of these free radicals transport in and around an arteriole during oxidative stress. We investigated the role of O(2)(-) and ONOO(-) in inactivating vasoactive NO. The model predictions include (a) NO interactions with oxygen, O(2)(-), and ONOO(-) have relatively little effect on the NO level in the vascular smooth muscle under physiologic conditions; (b) superoxide diffuses only a few microns from its source, whereas peroxynitrite diffuses over a larger distance; and (c) reduced superoxide dismutase levels significantly increase O(2)(-) and peroxynitrite concentrations and decrease NO concentration. Model results indicate that the reduced NO bioavailability and enhanced peroxynitrite formation may vary depending on the location of oxidative stress in the microcirculation, which occurs at diverse vascular cell locations in diabetes, aging, and cardiovascular diseases. The results will have significant implications for our understanding of these free radical interactions in physiologic and pathophysiologic conditions resulting from endothelial dysfunction.     

Expression of nitric oxide,peroxynitrite, and apoptosis in loose total hip replacements

Nitric oxide (NO) is an effector molecule associated with inflammation, immune function, bone metabolism, and the induction of apoptosis. This study examined the role of NO, peroxynitrite (ONOO(-)), and apoptosis in cases of revision total hip replacements (THRs). We hypothesized that apoptosis and excess production of NO contribute to the inflammatory reaction to orthopedic biomaterial wear debris that is associated with loosening and osteolysis. Periprosthetic membranous specimens were collected from revised cemented acetabular components with simple loosening and ballooning osteolysis. Synovial samples from patients undergoing primary THR were used as controls. The presence of macrophages (CD68(+)) and levels of inducible nitric oxide synthase (INOS), endothelial nitric oxide synthase (EcNOS), ONOO(-) (Nitro, assayed by the amount of nitrated tyrosine residues), and apoptosis (TUNEL staining) were examined using immunohistochemistry. Increased expression for INOS, EcNOS, and ONOO(-) in both the loose/osteolytic and the loose/non-osteolytic groups was observed when compared to the synovium group. There were no significant differences between the loose/osteolytic group and loose/non-osteolytic group for these biologic markers. TUNEL staining showed a significant increase in apoptosis in the loose/osteolytic group compared to the loose/non-osteolytic group and synovial tissues. These findings suggest that NO and NO-derived molecules, such as ONOO(-), may be involved in sustaining the foreign-body reaction to wear debris. NO and ONOO(-) may prove to be useful markers of prosthetic loosening whereas apoptosis may be a marker distinguishing ballooning from simple osteolysis.     

Resistance of macrophages to Mycobacterium avium is induced by alpha2-adrenergic stimulation

The ability of macrophages to control the growth of microorganisms is increased by macrophage activation. Previously, it was shown that epinephrine activated mouse macrophages to resist the growth of Mycobacterium avium via alpha(2)-adrenergic stimulation. In the present study, we show that the alpha(2)-adrenergic agonist (alpha(2)-agonist) clonidine induced resistance to M. avium growth in the RAW264.7 mouse macrophage cell line. The ability of catecholamines to induce resistance to mycobacteria was specific to alpha(2)-adrenergic stimulation, as alpha(1)-, beta(1)-, and beta(2)-agonists had no effect. Receptor signaling through Gi proteins was required. A G-protein antagonist specific for the alpha subunits of the Go/Gi family blocked the increased resistance induced by clonidine, while a Gs-protein antagonist was without effect. Both nitric oxide (NO) production and superoxide (O(2)(-)) production were required for the increased resistance to M. avium growth induced by clonidine. Although NO production was required, clonidine did not increase the level of NO in M. avium-infected cells. Since NO and O(2)(-) interact to produce peroxynitrite (ONOO(-)), we examined whether ONOO(-) mediates the increased resistance to M. avium induced by clonidine. 5,10,15,20-Tetrakis(4-sulfonatophenyl)prophyrinato iron (III) chloride (FeTPPS), a specific scavenger of ONOO(-), inhibited the effect of clonidine on M. avium growth. Clonidine also increased the production of ONOO(-) in M. avium-infected RAW264.7 cells, as measured by the oxidation of 123-dihydrorhodamine and the production of nitrated tyrosine residues. We therefore conclude that alpha(2)-adrenergic stimulation activates macrophages to resist the growth of M. avium by enhancing the production of ONOO(-).     

Human-bacteria nitric oxide cycles in HIV-1 infection

The human intestinal tract harbors a complex microbiotic environment containing commensal bacteria and immunocompetent mucosal cells. There is considerable communication between the bacteria and host cells through dietary constituents and metabolic cycles. We propose that in the pathogenesis of acquired immunodeficiency syndrome (AIDS), the human immunodeficiency virus-1 (HIV-1) triggers a change in a coupled transorganism (human-bacteria) nitric oxide interchange cycle, that may influence the biosynthesis and recycling of nitric oxide (NO) in AIDS patients. Normally, nitric oxide (NO) is produced from arginine through nitrate NO(3)(-), which is ultimately eliminated in the urine and feces. In HIV infection, however, the NO(3)(-) is converted into NO and nitrite NO(2)(-) and recirculated in the body, perhaps as a result of concomitant opportunistic bacterial infections and cellular hypoxia. Due to the efficient coupling of the human-bacteria nitric oxide cycles, persistently high levels of nitrite and the free radicals peroxynitrite (ONOO(-)) may occur in AIDS patients, contributing to the etiology of AIDS-related dementia, persistent immunosuppression and Kaposi's sarcoma.     

Peroxynitrite mediates cytokine-induced IL-8 gene expression and production by human leukocytes

Recent studies indicate that nitric oxide (NO) or related compounds may regulate the production of interleukin (IL)-8, a potent proinflammatory chemokine. Here we report that peroxynitrite (ONOO(-)) formed by a reaction of NO with superoxide mediates IL-8 gene expression and IL-8 production in IL-1beta- and TNF-alpha-stimulated human leukocytes in whole blood. The NO synthase inhibitors aminoguanidine and N(G)-nitro-L-arginine methyl ester blocked nuclear accumulation of activator protein-1 (AP-1) and nuclear factor (NF)-kappaB in both polymorphonuclear (PMN) and mononuclear leukocytes and inhibited IL-8 mRNA expression and IL-8 release by approximately 90% in response to IL-1beta and TNF-alpha. Enhanced ONOO(-) formation was detected in granulocytes, monocytes, and lymphocytes after challenge with IL-1beta or TNF-alpha. The addition of ONOO(-) (0.2-80 microM) to whole blood increased nuclear accumulation of AP-1 and NF-kappaB in PMN and mononuclear leukocytes and augmented IL-8 mRNA expression and IL-8 production in a concentration-dependent fashion. Pyrrolidine dithiocarbamate, an inhibitor of NF-kappaB activation, attenuated approximately 70% of IL-8 release evoked by IL-1beta, TNF-alpha, or ONOO(-). These results indicate that ONOO(-) formation may underlie the action of cytokines towards IL-8 gene expression in human leukocytes.     

Acid-dependent dismutation of nitrogen oxides may be a critical source of nitric oxide in human macrophages

The cytotoxic activity of the macrophage relies greatly on the secretion of a number of reactant intermediates, including superoxide (O(2)(-)), hydroxyl radical (OH(-)) and nitric oxide (NO). The latter, synthesized via cytokine-mediated induction of inducible NO-synthase (iNOS), is readily observed in murine macrophages. However, a poorly reproducible or minimal response to cytokine-stimulation in the human macrophage has questioned the presence or significance of this important pathway in man. Nevertheless, iNOS is present in other human phagocytic cells, e.g. neutrophils, while the NO metabolites, nitrite (NO(2)(-)) and nitrate (NO(3)(-)), are raised in human serum during infection. Low phagolysosomal pH is critical for the macrophage to destroy the engulfed pathogen. This acidic environment may allow synthesis of NO independently of iNOS via dismutation of NO(2)(-)to NO. Should this mechanism be active, assay for iNOS and NO by determination of NO(2)(-)could be misleading. In human macrophages, acid-induced conversion of imported nitrogen oxides (NOx) may take precedence over iNOS-mediated NO synthesis and should be investigated as a source of NO in these cells.     

Peroxynitrite formation in radiation-induced salivary gland dysfunction in mice

Xerostomia frequently arises in patients with head and neck malignancies that are treated by radiation. However, the mechanisms responsible for the destruction of the salivary gland remain unknown. We previously established a xerostomia model of mice and identified the pathway through which nitric oxide (NO) affects the pathogenesis of radiation-induced salivary gland dysfunction. Although the toxicity of NO alone is modest, NO with superoxide anion (O2(*-)) rapidly forms peroxynitrite (ONOO), a more powerful toxic oxidant. In this study, we used the experimental model to examine: 1) when NO and O2(*-) production is maximum in the salivary gland after irradiation;2) whether peroxynitrite, as assessed by nitrotyrosine production, is responsible for salivary gland dysfunction; and 3) the effect of the iNOS selective inhibitor, aminoguanidine (AG), on nitrotyrosine formation. The increases in production of NO and O2(*-) in the salivary gland peaked on day 7 after irradiation. Nitrotyrosine detected immunohistochemically was significantly reduced by AG in the salivary gland. On the basis of these results, we concluded that NO together with O2(*-) forms the more reactive ONOO, which might be an important pathogenic factor in radiation-induced salivary gland dysfunction.     

Protective effect of melatonin and pinoline on nitric oxide-induced lipid and protein peroxidation in rat brain homogenates

Nitric oxide (NO) is a physiological neurotransmitter, a mediator of the excitatory neurotransmitter glutamate pathways that regulates several neuroendocrine functions, but excessive NO is toxic by itself and it interacts with superoxide radical (O(2)(-)) to form the peroxynitrite anion (ONOO(-)). Using rat brain homogenates, we investigated the effects of melatonin and pinoline in preventing the level of lipid peroxidation (LPO) and carbonyl contents in proteins induced by nitric oxide (NO) which was released by the addition of sodium nitroprusside (SNP). Lipid and protein peroxidation were estimated by quantifying malondialdehyde (MDA) and 4-hydroxyalkenal (4-HDA) concentrations and carbonyl contents, respectively. SNP increased MDA+4-HDA and carbonyl contents production in brain homogenates in a time and concentration dependent manner. Both, melatonin and pinoline reduced NO-induced LPO and carbonyl contents in a dose-dependent manner in concentrations from 0.03 to 3 mM and 1 to 300 microM, respectively. Under the in vitro conditions of this experiment, both antioxidants were more efficient in limiting SNP protein oxidation than lipid damage.     

Helicobacter pylori urease suppresses bactericidal activity of peroxynitrite via carbon dioxide production

Helicobacter pylori can produce a persistent infection in the human stomach, where chronic and active inflammation, including the infiltration of phagocytes such as neutrophils and monocytes, is induced. H. pylori may have a defense system against the antimicrobial actions of phagocytes. We studied the defense mechanism of H. pylori against host-derived peroxynitrite (ONOO(-)), a bactericidal metabolite of nitric oxide, focusing on the role of H. pylori urease, which produces CO(2) and NH(3) from urea and is known to be an essential factor for colonization. The viability of H. pylori decreased in a time-dependent manner with continuous exposure to 1 microM ONOO(-), i.e., 0.2% of the initial bacteria remained after a 5-min treatment without urea. The bactericidal action of ONOO(-) against H. pylori was significantly attenuated by the addition of 10 mM urea, the substrate for urease, whereas ONOO(-)-induced killing of a urease-deficient mutant of H. pylori or Campylobacter jejuni, another microaerophilic bacterium lacking urease, was not affected by the addition of urea. Such a protective effect of urea was potentiated by supplementation with exogenous urease, and it was almost completely nullified by 10 microM flurofamide, a specific inhibitor of urease. The bactericidal action of ONOO(-) was also suppressed by the addition of 20 mM NaHCO(3) but not by the addition of 20 mM NH(3). In addition, the nitration of L-tyrosine of H. pylori after treatment with ONOO(-) was significantly reduced by the addition of urea or NaHCO(3), as assessed by high-performance liquid chromatography with electrochemical detection. These results suggest that H. pylori-associated urease functions to produce a potent ONOO(-) scavenger, CO(2)/HCO(3)(-), that defends the bacteria from ONOO(-) cytotoxicity. The protective effect of urease may thus facilitate sustained bacterial colonization in the infected gastric mucosa.     

An Inhibitor of Inducible Nitric Oxide Synthase and Scavenger of Peroxynitrite Prevents Diabetes Development in NOD Mice

Peroxynitrite (ONOO(-)) is a highly reactive oxidant produced by the interaction of the free radicals superoxide (O*-2) and nitric oxide (NO(*)). In a previous study, we found that peroxynitrite is formed in islet beta-cells of nonobese diabetic (NOD) mice. Here, we report that guanidinoethyldisulphide (GED), a selective inhibitor of inducible nitric oxide synthase (iNOS) and scavenger of peroxynitrite prevents diabetes in NOD mice. GED treatment of female NOD mice, starting at age 5 weeks, delayed diabetes onset (from age 12 to 22 weeks) and significantly decreased diabetes incidence at 30 weeks (from 80% to 17%). GED did not prevent pancreatic islet infiltration by leukocytes; however, beta-cells that stained positive for nitrotyrosine (a marker of peroxynitrite) were significantly decreased in islets of GED-treated mice (1+/-1%) compared with vehicle-treated mice (30+/-9%). In addition, GED significantly inhibited nitric oxide and nitrotyrosine formation and decreased destruction of beta-cells in NOD mouse islets incubated in vitro with the combination of proinflammatory cytokines interleukin 1-beta (IL-1beta), tumour necrosis factor-alpha (TNF-alpha) and interferon-gamma (IFN-gamma). These findings indicate that both superoxide and nitric oxide radicals contribute to islet beta-cell destruction in autoimmune diabetes via peroxynitrite formation in the beta-cells.     

Ischemic damage increases nitric oxide production via inducible nitric oxide synthase in the cochlea

The present study was designed to elucidate the dynamic changes of nitric oxide (NO) production in the perilymph and to investigate the immunostaining for inducible nitric oxide synthase (iNOS) in the cochlea for 7 days after transient cochlear ischemia. Moreover, aminoguanidine, which is a selective iNOS inhibitor, was administrated immediately following ischemia and every 24h thereafter for 7 days to investigate whether the production of NO is dependent on the iNOS pathway. Significant increases in the oxidative NO metabolites, nitrite (NO(2)(-)) and nitrate (NO(3)(-)), were measured on day 1 using an in vivo microdialysis and on-line high performance liquid chromatography (HPLC) system. The immunostaining for iNOS was strongly expressed on days 1 and 4 and returned to normal on day 7 after the ischemia. The administration of aminoguanidine reduced the oxidative NO metabolites on day 1 and suppressed the expression of iNOS. These findings suggest that transient ischemia causes a remarkable increase in NO production in the perilymph, which might be attributable to the iNOS pathway.     

Nitric oxide and peroxynitrite in postischemic myocardium

Alterations in the production of nitric oxide (NO.) are a critical factor in the injury that occurs in ischemic and reperfused myocardium; however, controversy remains regarding the alterations in NO. that occur and how these alterations cause tissue injury. As superoxide generation occurs during the early period of reperfusion, the cytotoxic oxidant peroxynitrite (ONOO-) could be formed; however, questions remain regarding ONOO- formation and its role in postischemic injury. Electron paramagnetic resonance spin trapping studies, using the NO. trap Fe(2+)-N-methyl-D-glucamine dithiocarbamate (Fe-MGD), and chemiluminescence studies, using the enhancer luminol, have been performed to measure the magnitude and time course of NO. and ONOO- formation in the normal and postischemic heart. Isolated rat hearts were subjected to control perfusion, or ischemia followed by reperfusion in the presence of Fe-MGD with electron paramagnetic resonance measurements performed on the effluent from these hearts. Whereas only trace signals were present prior to ischemia, prominent NO. adduct signals were seen during the first 2 min of reflow. The reperfusion associated increase in these NO. signals was abolished by nitric oxide synthase inhibition. In hearts perfused with luminol to detect ONOO- formation, a similar marked increase was seen during the first 2 min of reperfusion that was blocked by nitric oxide synthase inhibitors and by superoxide dismutase. Either NG-nitro-L-arginine methyl ester or superoxide dismutase treatment resulted in more than twofold higher recovery of contractile function than in untreated hearts. Immunohistology studies demonstrated that the ONOO(-)-mediated nitration product nitrotyrosine was formed in postischemic hearts, but not in normally perfused controls. Thus, NO. formation is increased during the early period of reperfusion and reacts with superoxide to form ONOO-, which results in protein nitration and myocardial injury.     

The role of free radicals in the muscle vasodilatation of systemic hypoxia in the rat

Muscle vasodilatation evoked by systemic hypoxia is adenosine mediated and nitric oxide (NO) dependent: recent evidence suggests the increased binding of NO at complex IV of endothelial mitochondria when O(2) level falls leads to adenosine release. In this study on anaesthetised rats, the increase in femoral vascular conductance (FVC) evoked by systemic hypoxia (breathing 8 % O(2) for 5 min) was reduced by oxypurinol which inhibits xanthine oxidase (XO): XO generates O(2)(-) from hypoxanthine, a metabolite of adenosine. By contrast, infusion of superoxide dismutase (SOD), which dismutes O(2)(-) to hydrogen peroxide (H(2)O(2)), potentiated the hypoxia-evoked increase in FVC. However, NO synthesis inhibition reduced the hypoxia-evoked increase in FVC and it was not further altered by SOD. In other studies, the spinotrapezius muscle was pre-loaded with hydroethidine (HE), or dihydrorhodamine (DHR) which fluoresce in the presence of O(2)(-) and H(2)O(2), respectively. In muscle loaded with HE, systemic hypoxia increased fluorescence in endothelial cells of arterioles, whereas in muscle loaded with DHR, fluorescence was diffusely located in and around arteriolar endothelium. We propose that in systemic hypoxia, O(2)(-) generated by the XO degradation pathway from adenosine released by endothelial cells, and released by endothelial mitochondria by increased binding of NO to complex IV, is dismuted to H(2)O(2), which facilitates hypoxia-induced dilatation.     

The two faces of endothelial nitric oxide synthase in the pathophysiology of atherosclerosis.

In the endothelium, nitric oxide (NO) is constitutively generated from the conversion of L-arginine to L-citrullin by the enzymatic action of endothelial NO synthase (eNOS). An impairment of endothelium-dependent relaxation (EDR) is present in atherosclerotic vessels even before vascular structural changes occur, and represents the reduced eNOS-derived NO activity. Because of its multiple biological actions, NO from eNOS is believed to act as an anti-atherogenic molecule. On the other hand, there is increased production of superoxide in atherosclerotic vessels, which promotes atherogenesis. Recently it is revealed that eNOS becomes dysfunctional and produces superoxide rather than NO under various pathological conditions in which tissue levels of BH4 are reduced. The pathological role of dysfunctional eNOS has attracted attentions in vascular disorders including atherosclerosis, in which abnormal pteridine metabolisms in vascular tissue including decreased BH4 levels and increased BH2 levels have been demonstrated. The presence of dysfunctional eNOS may not only impair EDR but also accelerate lesion formation in atherosclerotic vessels. This review focuses on two faces of eNOS as both an NO- as well as superoxide-producing enzyme depending on tissue pteridine metabolisms in the pathophysiology of atherosclerosis.     

A nitric oxide-releasing reagent, S-nitroso-N-acetylpenicillamine, enhances the expression of superoxide dismutases mRNA in the murine macrophage cell line RAW264-7.

Murine interferon-gamma (IFN-gamma) stimulates the murine macrophage tumour cell line RAW264-7 to produce nitric oxide (NO). IFN-gamma induces expression of inducible NO synthase (iNOS), manganese superoxide dismutase (Mn-SOD) and copper zinc SOD (CuZn-SOD) in these cells. To investigate the mechanism of induction of SOD expression, we added S-nitroso-N-acetyl penicillamine (SNAP) to RAW264-7 cells. SNAP enhanced the expression of Mn-SOD and CuZn-SOD. These results suggest that when producing NO, RAW264-7 cells express SOD that might protect them from NO toxicity.     

Dual effect of nitric oxide on SARS-CoV replication: Viral RNA production and palmitoylation of the S protein are affected

Nitric oxide is an important molecule playing a key role in a broad range of biological process such as neurotransmission, vasodilatation and immune responses. While the anti-microbiological properties of nitric oxide-derived reactive nitrogen intermediates (RNI) such as peroxynitrite, are known, the mechanism of these effects are as yet poorly studied. Severe Acute Respiratory Syndrome coronavirus (SARS-CoV) belongs to the family Coronaviridae, was first identified during 2002-2003. Mortality in SARS patients ranges from between 6 to 55%. We have previously shown that nitric oxide inhibits the replication cycle of SARS-CoV in vitro by an unknown mechanism. In this study, we have further investigated the mechanism of the inhibition process of nitric oxide against SARS-CoV. We found that peroxynitrite, an intermediate product of nitric oxide in solution formed by the reaction of NO with superoxide, has no effect on the replication cycle of SARS-CoV, suggesting that the inhibition is either directly effected by NO or a derivative other than peroxynitrite. Most interestingly, we found that NO inhibits the replication of SARS-CoV by two distinct mechanisms. Firstly, NO or its derivatives cause a reduction in the palmitoylation of nascently expressed spike (S) protein which affects the fusion between the S protein and its cognate receptor, angiotensin converting enzyme 2. Secondly, NO or its derivatives cause a reduction in viral RNA production in the early steps of viral replication, and this could possibly be due to an effect on one or both of the cysteine proteases encoded in Orf1a of SARS-CoV.     

一氧化氮和过氧亚硝基阴离子在肢体缺血再灌注致肺损伤中的作用

目的:观察肢体缺血再灌注致肺损伤时肺组织中一氧化氮(NO)及过氧亚硝基阴离子(ONOO^-)的变化,以探讨二者在此种损伤中的作用。方法:采用夹闭大鼠腹主动脉下段造成双下肢缺血和再灌注后肺损伤模型,分别测定假手术组、缺血4h组、缺血4h再灌注1h组及再灌注4h组肺组织匀浆中超氧化物歧化酶(SOD)活性和丙二醛(MDA)、NO₂^-/NO₃^-含量变化;应用免疫组化方法测定上述各组肺组织中诱导型一氧化氮合酶(iNOS)及ONOO^-体内生成标志物硝基酪氨酸(NT)的变化。结果:肢体缺血再灌注后1h和4h肺组织中MDA和NO₂^-/NO₃^-的含量显著高于对照组和单纯缺血组(P＜0.05),而SOD活性则显著低于此两组(P＜0.05),并出现大量iNOS及NT阳性信号。结论:肢体缺血再灌注致肺损伤时肺组织中有大量NO和ONOO^-产生,脂质过氧化增强,提示ONOO^-参与介导此种肺损伤。