T cell activation-induced mitochondrial hyperpolarization is mediated by Ca2+- and redox-dependent production of nitric oxide

Activation, proliferation, or programmed cell death of T lymphocytes is regulated by the mitochondrial transmembrane potential (Deltapsi(m)) through controlling ATP synthesis, production of reactive oxygen intermediates (ROI), and release of cell death-inducing factors. Elevation of Deltapsi(m) or mitochondrial hyperpolarization is an early and reversible event associated with both T cell activation and apoptosis. In the present study, T cell activation signals leading to mitochondrial hyperpolarization were investigated. CD3/CD28 costimulation of human PBL elevated cytoplasmic and mitochondrial Ca(2+) levels, ROI production, and NO production, and elicited mitochondrial hyperpolarization. Although T cell activation-induced Ca(2+) release, ROI levels, and NO production were diminished by inositol 1,4,5-triphosphate receptor antagonist 2-aminoethoxydiphenyl borane, superoxide dismutase mimic manganese (III) tetrakis (4-benzoic acid) porphyrin chloride, spin trap 5-diisopropoxyphosphoryl-5-methyl-1-pyrroline-N-oxide, and NO chelator carboxy-2-phenyl-4,4,5,5-tetramethyl-imidazoline-1-oxyl-3-oxide, mitochondrial hyperpolarization was selectively inhibited by carboxy-2-phenyl-4,4,5,5-tetramethyl-imidazoline-1-oxyl-3-oxide (-85.0 +/- 10.0%; p = 0.008) and, to a lesser extent, by 2-aminoethoxydiphenyl borane. Moreover, NO precursor (Z)-1-[2-(2-aminoethyl)-N-(2-ammonioethyl)amino]diazen-1-ium-1,2-diolate diethylenetriamine elicited NO and ROI production, Ca(2+) release, transient ATP depletion, and robust mitochondrial hyperpolarization (3.5 +/- 0.8-fold; p = 0.002). Western blot analysis revealed expression of Ca-dependent endothelial NO synthase and neuronal NO synthase isoforms and absence of Ca-independent inducible NO synthase in PBL. CD3/CD28 costimulation or H(2)O(2) elicited severalfold elevations of endothelial NO synthase and neuronal NO synthase expression, as compared with beta-actin. H(2)O(2) also led to moderate mitochondrial hyperpolarization; however, Ca(2+) influx by ionomycin or Ca(2+) release from intracellular stores by thapsigargin alone failed to induce NO synthase expression, NO production, or Deltapsi(m) elevation. The results suggest that T cell activation-induced mitochondrial hyperpolarization is mediated by ROI- and Ca(2+)-dependent NO production.     

Nitric oxide donors, nitrosothiols and mitochondrial respiration inhibitors induce caspase activation by different mechanisms

We investigated to what extent different types of NO donors induce caspase activation by opening of the mitochondrial permeability transition pore (PTP) or inhibition of mitochondrial respiration. We found that nitrosothiols can directly open the PTP in isolated mitochondria and cause cytochrome c release, whereas NONOate donors can not. In macrophages nitrosothiols cause caspase activation that is blocked by cyclosporin A or calcium chelation, both of which prevent PTP opening, whereas caspase activation caused by NONOates is much less sensitive to these agents. Inhibitors of mitochondrial respiration did not promote PTP opening in isolated mitochondria, and although they cause caspase activation in macrophages, this activation was slower than that caused by NO donors, and was relatively insensitive to cyclosporin and calcium chelators suggesting that PTP opening was not involved.     

Nitric oxide and mitochondrial complex IV

Micromolar nitric oxide (NO) rapidly (ms) inhibits cytochrome c oxidase in turnover with physiological substrates. Two reaction mechanisms have been identified leading, respectively, to formation of a nitrosyl- [a3(2+) -NO] or a nitrite- [a3(3+) -NO2-] derivative of the enzyme. In the presence of O2, the nitrosyl adduct recovers activity slowly, following NO displacement at k' approximately equal to 0.01 s(-1) (37 degrees C); the recovery of the nitrite adduct is much faster. Relevant to pathophysiology, the enzyme does not degrade NO by following the first mechanism, whereas by following the second one it promotes NO oxidation and disposal as nitrite/nitrate. The reaction between NO and cytochrome c oxidase has been investigated at different integration levels of the enzyme, including the in situ state, such as in mouse liver mitochondria or cultured human SY5Y neuroblastoma cells. The respiratory chain is inhibited by NO, either supplied exogenously or produced endogenously via the NO synthase activation. Inhibition of respiration is reversible, although it remains to be clarified whether reversibility is always full and how it depends on concentration of and time of exposure to NO. Oxygraphic measurements show that cultured cells or isolated state 4 mitochondria exposed to micromolar (or less) NO recover from NO inhibition rapidly, as if the nitrite reaction was predominant. Mitochondria in state 3 display a slightly more persistent inhibition than in state 4, possibly due to a higher accumulation of the nitrosyl adduct. Among a number of parameters that appear to control the switch over between the two mechanisms, the concentration of reductants (reduced cytochrome c) at the cytochrome c oxidase site has been proved to be the most relevant one.     

Nitric oxide and mitochondrial respiration.

Nitric oxide (NO) and its derivative peroxynitrite (ONOO-) inhibit mitochondrial respiration by distinct mechanisms. Low (nanomolar) concentrations of NO specifically inhibit cytochrome oxidase in competition with oxygen, and this inhibition is fully reversible when NO is removed. Higher concentrations of NO can inhibit the other respiratory chain complexes, probably by nitrosylating or oxidising protein thiols and removing iron from the iron-sulphur centres. Peroxynitrite causes irreversible inhibition of mitochondrial respiration and damage to a variety of mitochondrial components via oxidising reactions. Thus peroxynitrite inhibits or damages mitochondrial complexes I, II, IV and V, aconitase, creatine kinase, the mitochondrial membrane, mitochondrial DNA, superoxide dismutase, and induces mitochondrial swelling, depolarisation, calcium release and permeability transition. The NO inhibition of cytochrome oxidase may be involved in the physiological regulation of respiration rate, as indicated by the finding that isolated cells producing NO can regulate cellular respiration by this means, and the finding that inhibition of NO synthase in vivo causes a stimulation of tissue and whole body oxygen consumption. The recent finding that mitochondria may contain a NO synthase and can produce significant amounts of NO to regulate their own respiration also suggests this regulation may be important for physiological regulation of energy metabolism. However, definitive evidence that NO regulation of mitochondrial respiration occurs in vivo is still missing, and interpretation is complicated by the fact that NO appears to affect tissue respiration by cGMP-dependent mechanisms. The NO inhibition of cytochrome oxidase may also be involved in the cytotoxicity of NO, and may cause increased oxygen radical production by mitochondria, which may in turn lead to the generation of peroxynitrite. Mitochondrial damage by peroxynitrite may mediate the cytotoxicity of NO, and may be involved in a variety of pathologies.     

Nitric oxide inhibition of mitochondrial respiration and its role in cell death

Nitric oxide (NO) or its derivatives (reactive nitrogen species, RNS) inhibit mitochondrial respiration in two different ways: (i) an acute, potent, and reversible inhibition of cytochrome oxidase by NO in competition with oxygen; and, (ii) irreversible inhibition of multiple sites by RNS. NO inhibition of respiration may impinge on cell death in several ways. Inhibition of respiration can cause necrosis and inhibit apoptosis due to ATP depletion, if glycolysis is also inhibited or is insufficient to compensate. Inhibition of neuronal respiration can result in excitotoxic death of neurons due to induced release of glutamate and activation of NMDA-type glutamate receptors. Inhibition of respiration may cause apoptosis in some cells, while inhibiting apoptosis in other cells, by mechanisms that are not clear. However, NO can induce (and inhibit) cell death by a variety of mechanisms unrelated to respiratory inhibition.     

Nitric oxide suppresses apoptosis via interrupting caspase activation and mitochondrial dysfunction in cultured hepatocytes.

Nitric oxide (NO) is a potent inhibitor of apoptosis in many cell types, including hepatocytes. We and others have described NO-dependent decreases in caspase activity in cells undergoing apoptosis. However, previous work has not determined whether NO disrupts the proteolytic processing and thus the activation of pro-caspases. Here we report that NO suppresses proteolytic processing and activation of multiple pro-caspases in intact cells, including caspase-3 and caspase-8. We found that both exogenous NO as well as endogenously produced NO via adenoviral inducible NO synthase gene transfer protected hepatocytes from tumor necrosid factor (TNF) alpha plus actinomycin D (TNFalpha/ActD)-induced apoptosis. Affinity labeling with biotin-VAD-fmk of all active caspase species in TNFalpha-mediated apoptosis identified four newly labeled spots (activated caspases) present exclusively in TNFalpha/ActD-treated cells. Both NO and the caspase inhibitor, Ac-DEVD-CHO, prevented the appearance of the four newly labeled spots or active caspases. Immunoanalysis of affinity labeled caspases demonstrated that caspase-3 was the major effector caspase. Western blot analysis also identified the activation of caspase-8 in the TNFalpha/ActD-treated cells, and the activation was suppressed by NO. Furthermore, NO inhibited several other events associated with caspase activation in cells, including release of cytochrome c from mitochondria, decrease in mitochondrial transmembrane potential, and cleavage of poly(ADP-ribose) polymerase in TNFalpha/ActD-treated cells. These findings indicate the involvement of multiple caspases in TNFalpha-mediated apoptosis in hepatocytes and establish the capacity of NO to inhibit not only active caspases but also caspase activation.     

Nitric oxide induces apoptosis in a human colonic epithelial cell line, T84

Chronic inflammation is associated with inducible nitric oxide synthase expression in infiltrating and resident cells (epithelia, neurons) and an exaggerated release of nitric oxide. NO can induce apoptosis in macrophages and tumour cell lines. We investigated whether NO induced cell death in an epithelial (T84) cell fine via apoptosis. Culture T84 cells were exposed to a bolus of NO (40 or 80 muM) dissolved in Hank's balanced salt solution (HBSS) supplemented with 10% fetal calf serum (FCS). After incubation for 4 h at 37( degrees )C in 5% CO(2), cells were either stained for DNA fragmentation with the TdT-mediated dUTP-biotin nick end labelling (TUNEL) method, or cytosolic DNA fragments quantified by a cell death detection ELISA assay. Nitric oxide induced apoptosis in a dose-dependent manner which preceded frank cell death (failure to exclude Trypan blue). These data suggest that epithelial cell death may be NO dependent and via apoptosis, in states of gut inflammation.     

Nitric oxide and metastatic cell behaviour

Nitric oxide (NO) is a pleiotropic signalling molecule that subserves a wide variety of basic cellular functions and also manifests itself pathophysiologically. As regards cancer and its progression, however, the reported role of NO appears surprisingly inconsistent. In this review, we focus on metastasis, the process of cancer cell spread and secondary tumour formation. In a 'reductionist' approach, we consider the metastatic cascade to be made up of a series of basic cellular behaviours (such as proliferation, apoptosis, adhesion, secretion migration, invasion and angiogenesis). We evaluate how NO controls such behaviours, in comparison with normal cells. The available information suggests strongly that NO signalling would be expected to regulate these behaviours both positively and negatively and this probably leads to the observed apparent variability in the NO status of cancer cells and tissues. Thus, the role of NO in cancer is more complex than previously thought. A number of suggestions are made, including consideration of novel mechanisms, such as ion channels, in order to achieve a more consistent and integrated understanding of NO signalling in cancer and to realise its clinical potential.     

Nitric oxide and mitochondrial status in noise-induced hearing loss

This study investigated the distribution of nitric oxide (NO) within isolated outer hair cells (OHCs) from the cochlea, its relationship to mitochondria and its modulation of mitochondrial function. Using two fluorescent dyes—4,5-diaminofluorescein diacetate (DAF-2DA), which detects NO, and tetramethyl rhodamine methyl ester (TMRM⁺), a mitochondrial membrane potential dye—it was found that a relatively greater amount of the DAF fluorescence in OHCs co-localized with mitochondria in comparison to DAF fluorescence in the cytosole. This study also observed reduced mitochondrial membrane potential of OHCs and increased DAF fluorescence following exposure of the cells to noise (120 dB SPL for 4 h) and to an exogenous NO donor, NOC-7 (>350 nm). Antibody label for nitrotyrosine was also increased, indicating NO-related formation of peroxynitrite in both mitochrondria and the cytosol. The results suggest that NO may play an important physiological role in regulating OHC energy status and act as a potential agent in OHC pathology.     

Nitric oxide and cell death.

Nitric oxide (NO) has several essential roles in mammals, but unregulated NO production can cause cell death through oxidative stress, disrupted energy metabolism, DNA damage, activation of poly(ADP-ribose) polymerase, or dysregulation of cytosolic calcium. Such disturbances can lead to either apoptotic or necrotic cell death, depending on the severity and context of the damage. Here I review the mechanisms by which NO kills cells and discuss how NO thereby contributes to ischaemia-reperfusion injury and neurodegeneration.     

Nitric oxide and mitochondrial status in noise-induced hearing loss

The study investigated the distribution of nitric oxide (NO) within isolated outer hair cells (OHCs) from the cochlea, its relationship to mitochondria and its modulation of mitochondrial function. Using two fluorescent dyes--4,5-diamino-fluorescein diacetate (DAF-2DA), which detects NO, and tetramethyl rhodamine methyl ester (TMRM+), a mitochondrial membrane potential dye--it was found that a relatively greater amount of the DAF fluorescence in OHCs co-localized with mitochondria in comparison to DAF fluorescence in the cytosole. This study also observed reduced mitochondrial membrane potential of OHCs and increased DAF fluorescence following exposure of the cells to noise (120 dB SPL for 4 h) and to an exogenous NO donor, NOC-7 (>350 mm). Antibody label for nitrotyrosine was also increased, indicating NO-related formation of peroxynitrite in both mitochondria and the cytosol. The results suggest that NO may play an important physiological role in regulating OHC energy status and act as a potential agent in OHC pathology.     

Nitric oxide affects plant mitochondrial functionality in vivo

In this report, we show that nitric oxide affects mitochondrial functionality in plant cells and reduces total cell respiration due to strong inhibition of the cytochrome pathway. The residual respiration depends on the alternative pathway and novel synthesis of alternative oxidase occurs. These modifications are associated with depolarisation of the mitochondrial membrane potential and release of cytochrome c from mitochondria, suggesting a conserved signalling pathway in plants and animals. This signal cascade is triggered at the mitochondrial level and induces about 20% of cell death. In order to achieve a higher level of cell death, the addition of H(2)O(2) is necessary.     

Nitric oxide and hypoxia exacerbate alcohol-induced mitochondrial dysfunction in hepatocytes

Chronic alcohol consumption results in hepatotoxicity, steatosis, hypoxia, increased expression of inducible nitric oxide synthase (iNOS) and decreased activities of mitochondrial respiratory enzymes. The impact of these changes on cellular respiration and their interaction in a cellular setting is not well understood. In the present study we tested the hypothesis that nitric oxide (NO)-dependent modulation of cellular respiration and the sensitivity to hypoxic stress is increased following chronic alcohol consumption. This is important since NO has been shown to regulate mitochondrial function through its interaction with cytochrome c oxidase, although at higher concentrations, and in combination with reactive oxygen species, can result in mitochondrial dysfunction. We found that hepatocytes isolated from alcohol-fed rats had decreased mitochondrial bioenergetic reserve capacity and were more sensitive to NO-dependent inhibition of respiration under room air and hypoxic conditions. We reasoned that this would result in greater hypoxic stress in vivo, and to test this, wild-type and iNOS(-/-) mice were administered alcohol-containing diets. Chronic alcohol consumption resulted in liver hypoxia in the wild-type mice and increased levels of hypoxia-inducible factor 1 α in the peri-venular region of the liver lobule. These effects were attenuated in the alcohol-fed iNOS(-/-) mice suggesting that increased mitochondrial sensitivity to NO and reactive nitrogen species in hepatocytes and iNOS plays a critical role in determining the response to hypoxic stress in vivo. These data support the concept that the combined effects of NO and ethanol contribute to an increased susceptibility to hypoxia and the deleterious effects of alcohol consumption on liver.