Excitotoxic mitochondrial depolarisation requires both calcium and nitric oxide in rat hippocampal neurons

Nitric-oxide-induced depolarization of neuronal mitochondria: implications for neuronal cell death

Nitric oxide (NO(*)) has known toxic effects on central nervous system neurons. This study characterized the effect of NO(*) on mitochondrial membrane changes by exploring the relationship among NO(*), excitatory receptor activation, and the induction of peroxynitrite, a highly toxic NO(*) reactant, to neuronal injury. Cultured rat cortical neurons were exposed to the NO(*) generator, diethylenetriamine/nitric oxide adduct, and were examined for signs of cell death, mitochondrial membrane potential changes (Deltapsi(m)), and the induction of a mitochondrial permeability transition (MPT). Neurons were also examined for nitrotyrosine (NT) immunoreactivity, a marker of reactive nitrogen species (RNS) formation. Neurons exposed to NO(*) or to N-methyl-D-aspartate (NMDA) exhibited similar rapid depolarization of mitochondria, which was prevented by an NMDA receptor antagonist. Electrophysiological studies demonstrated NO(*) potentiation of NMDA-induced NMDA receptor currents. NO(*) and NMDA-treated neurons had evidence of mitochondrial-specific NT immunoreactivity that was prevented by a SOD/catalase mimetic (EUK-134). EUK-134 treatment reduced both NO(*) and NMDA-induced NT formation and neuronal cell death. EUK-134 did not prevent NO-induced Deltapsi(m) but partially prevented NMDA-induced Deltapsi(m) loss. Although NO(*) and NMDA both induced MPT and MPT inhibitors prevented NO-induced Deltapsi(m), they did not result in significant neuroprotection, in contrast to treatment designed to decrease peroxynitrite formation. These data suggest that NO-induced NMDA receptor activation is closely linked to intramitochondrial NO-peroxynitrite/RNS formation and thereby acts as a major mediator of neuronal cell death.

Inflammatory neurodegeneration mediated by nitric oxide, glutamate, and mitochondria

In inflammatory, infectious, ischemic, and neurodegenerative pathologies of the central nervous system (CNS) glia become "activated" by inflammatory mediators, and express new proteins such as the inducible isoform of nitric oxide synthase (iNOS). Although these activated glia have benefi- cial roles, in vitro they potently kill cocultured neurons, and there is increasing evidence that they contribute to pathology in vivo. Nitric oxide (NO) from iNOS appears to be a key mediator of such glial-induced neuronal death. The high sensitivity of neurons to NO is partly due to NO causing inhibition of respiration, rapid glutamate release from both astrocytes and neurons, and subsequent excitotoxic death of the neurons. NO is a potent inhibitor of mitochondrial respiration, due to reversible binding of NO to cytochrome oxidase in competition with oxygen, resulting in inhibition of energy production and sensitization to hypoxia. Activated astrocytes or microglia cause a potent inhibition of respiration in cocultured neurons due to glial NO inhibiting cytochrome oxidase within the neurons, resulting in ATP depletion and glutamate release. In some conditions, glutamate- induced neuronal death can itself be mediated by N-methyl-D-aspartate (NMDA)-receptor activation of the neuronal isoform of NO synthase (nNOS) causing mitochondrial damage. In addition NO can be converted to a number of reactive derivatives such as peroxynitrite, NO2, N2O3, and S-nitrosothiols that can kill cells in part by inhibiting mitochondrial respiration or activation of mitochondrial permeability transition, triggering neuronal apoptosis or necrosis.

The Yin and Yang of NMDA receptor signalling

Ca(2+) entry through the NMDA subtype of glutamate receptors has the power to determine whether neurons survive or die. Too much NMDA receptor activity is harmful to neurons - but so is too little. Is it a case of too much or too little Ca(2+) influx causing cell death or do other factors, such as receptor location or receptor-associated proteins, play a role? Understanding the mechanisms behind this dichotomous signalling is an important area of molecular neuroscience with direct clinical implications.

Nitric oxide-induced mitochondrial dysfunction: implications for neurodegeneration

Excessive generation of nitric oxide (NO) has been implicated in the pathogenesis of several neurodegenerative disorders. Damage to the mitochondrial electron transport chain has also been implicated in these disorders. NO and its toxic metabolite peroxynitrite (ONOO(-)) can inhibit the mitochondrial respiratory chain, leading to energy failure and ultimately cell death. There appears to be a differential susceptibility of brain cell types to NO/ONOO(-), which may be influenced by factors including cellular antioxidant status and the ability to maintain energy requirements in the face of marked respiratory chain damage. Although formation of NO/ONOO(-) following cytokine exposure does not affect astrocyte survival, these molecules may diffuse out and cause mitochondrial damage to neighboring NO/ONOO(-)-sensitive cells such as neurons. Evidence suggests that NO/ONOO(-) causes release of neuronal glutamate, leading to glutamate-induced activation of neuronal NO synthase and generation of further damaging species. While neurons appear able to recover from short-term exposure to NO/ONOO(-), extending the period of exposure results in persistent damage to the respiratory chain and cell death ensues. These findings have important implications for acute infection vs. chronic neuroinflammatory disease states. The evidence for NO/ONOO(-)-mediated mitochondrial damage in neurodegenerative disorders is reviewed and potential therapeutic strategies are discussed.

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.

Optical scatter imaging detects mitochondrial swelling in living tissue slices

Mitochondrial swelling is observed in neuronal injury and is a key event in many pathways to cell death. Currently, there is no technique for directly measuring mitochondrial size changes within living tissue slices with a field of view of several millimeters. In this paper, we test our hypothesis that Mie light-scatter theory can be used to study mitochondrial swelling in living tissue sections. Using a unique dual-angle scatter ratio (DASR) optical imaging system previously demonstrated to be sensitive to latex particle size changes and N-methyl-D-aspartate (NMDA) treatment of hippocampal slices, we studied mitochondrial swelling induced by 500 microM NMDA treatment of hippocampal slices. We observed a strong (R(2) = 0.73) and significant (P < 0.000005) correlation between the electron microscopy-determined diameters of swollen, intact mitochondria and the DASR imaging. We examined the robustness of the technique by evaluating the correlation between the dual-angle scatter ratio and the diameter of the dendrites, observed to swell, in NMDA-treated slices and found no correlation (R(2) = 0.06). The advantage of DASR imaging over electron microscopy or other methods of studying mitochondrial swelling is the sensitivity of DASR imaging to mitochondrial swelling over a large field of view (>9 mm(2)) in an intact tissue slice. This novel technique may allow for the study of regional changes in mitochondrial swelling and recovery as sequential events within a single specimen. This technique will eventually be useful in studying the efficacy of stroke and other disease therapies targeting mitochondrial swelling.

NO upregulation of a cyclic nucleotide-gated channel contributes to calcium elevation in endothelial cells

We investigated whether nitric oxide (NO) upregulates a cyclic nucleotide-gated (CNG) channel and whether this contributes to sustained elevation of intracellular calcium levels ([Ca(2+)](i)) in porcine pulmonary artery endothelial cells (PAEC). Exposure of PAEC to an NO donor, NOC-18 (1 mM), for 18 h increased the protein and mRNA levels of CNGA2 40 and 50%, respectively (P < 0.05). [Ca(2+)](i) in NO-treated cells was increased 50%, and this increase was maintained for up to 12 h after removal of NOC-18 from medium. Extracellular calcium is required for the increase in [Ca(2+)](i) in NO-treated cells. Thapsigargin induced a rapid cytosolic calcium rise, whereas both a CNG and a nonselective cation channel blocker caused a faster decline in [Ca(2+)](i), suggesting that capacitive calcium entry contributes to the elevated calcium levels. Antisense inhibition of CNGA2 expression attenuated the NO-induced increases in CNGA2 expression and [Ca(2+)](i) and in capacitive calcium entry. Our results demonstrate that exogenous NO upregulates CNGA2 expression and that this is associated with elevated [Ca(2+)](i) and capacitive calcium entry in porcine PAEC.

Nitric oxide promotes intracellular calcium release from mitochondria in striatal neurons

Overproduction of nitric oxide by NMDA receptor stimulation is implicated in calcium deregulation and neurodegeneration of striatal neurons. We investigated the involvement of nitric oxide (NO) in inducing intracellular calcium release and in modifying calcium transients evoked by NMDA. NO application (4-10 microM) reversibly and repeatedly increased the intracellular calcium concentration [Ca2+]i in Fura-2- or fluo-3-loaded cultured mouse striatal neurons. NO-induced [Ca2+]i responses persisted in the absence of extracellular calcium, indicating that Ca2+ was released from intracellular stores. The source of calcium was distinct from [Ca2+]i-activated (ruthenium red and ryanodine sensitive) or IP3-activated (thapsigargin-sensitive) Ca2+ stores and was not dependent on cGMP production because a cell permeant analog, 8-bromo-cGMP, did not increase basal [Ca2+]i. Glucose removal potentiated the NO-induced release of [Ca2+]i. In contrast, pretreatment with either the mitochondrial uncoupler carbonyl cyanide m-chlorophenylhydrazone or cyclosporin A, a blocker of the mitochondrial permeability transition pore, prevented the [Ca2+]i increase after NO. The rise in [Ca2+]i during NO exposure was preceded by a decrease in mitochondrial membrane potential that was partly reversible during washout. Repeated applications of NMDA induced irreversible [Ca2+]i responses in a subpopulation of striatal cells that were greatly reduced by the NOS inhibitor N omega-nitro-l-arginine. Calcium transients were prolonged by conjoint application of NMDA and NO. We conclude that NMDA-evoked [Ca2+]i transients are modulated by endogenous NO production, which leads to release of calcium from the mitochondrial pool. An NO-activated mitochondrial permeability transition pore may lead to cell death after overstimulation of NMDA receptors.

Nitric oxide modulates low-Mg2+-induced epileptiform activity in rat hippocampal-entorhinal cortex slices

The production of nitric oxide (NO) during low-Mg2+-induced epileptiform activity in rat hippocampal-entorhinal cortex slices was investigated by real-time monitoring using 1,2-diaminoanthraquinone (DAQ). NO reacts with the aromatic amino groups of DAQ at neutral pH and in the presence of oxygen to form the fluorescence product 1H-anthra-[1,2d]-[1,2,3]triazole-6,11-dione (ATD). The DAQ-induced formation of ATD required NO and was insensitive to radical oxygen species. Removal of Mg2+ ions from the artificial cerebrospinal fluid (ACSF) induced a significant elevation in the ATD fluorescence signal. The application of L-arginine (2 mM), a substrate of nitric oxide synthase (NOS), caused a comparable increase in the ATD fluorescence signal. Furthermore, ATD signal increase induced either by low-Mg2+ ACSF or by L-arginine was sensitive to N-nitro-L-arginine methyl ester (L-NAME), a NOS inhibitor. The application of L-NAME (200 microM) caused a complete blockade of low-Mg2+-induced epileptiform activity. Under this condition, increasing NO concentration by addition of the NO donor S-nitroso-N-acetylpenicillamine (200 microM) reinduced the epileptiform activity. It has been concluded that onset and maintenance of low-Mg2+-induced spontaneous epileptiform activity are modulated by NO concentration. Further NO imaging studies may help to elucidate the role of NO in detail and may bring to light new means for epilepsy therapy.

Mitochondria, Ca2+ and neurodegenerative disease

Mitochondria play a central role in cell biology not only as producers of ATP, but also in the sequestration of Ca(2+) and the generation of free radicals. They are also repositories of several proteins which regulate apoptosis. Perturbations in the normal functions of mitochondria will inevitably disturb cell function, may sensitise cells to neurotoxic insults and may initiate cell death. Neuronal Ca(2+) overload, such as follows excessive stimulation of Ca(2+) permeant excitatory amino acid receptors, can cause cell death. Recent evidence suggests that the accumulation of Ca(2+) into mitochondria during episodes of cellular Ca(2+) overload initiates a cascade of events that culminate in cell death. Cell death appears to require not only mitochondrial Ca(2+) overload, but rather a combination of raised intramitochondrial Ca(2+) concentration with increased production of nitric oxide and possibly other oxyradical species. Cell death may proceed through either necrotic or apoptotic mechanisms, depending on the rate of consumption and depletion of ATP. Evidence is also accumulating to suggest that more subtle alterations in mitochondrial function may serve as predisposing factors in the pathogenesis of a number of neurodegenerative disorders.

Extrasynaptic NMDARs oppose synaptic NMDARs by triggering CREB shut-off and cell death pathways

Here we report that synaptic and extrasynaptic NMDA (N-methyl-D-aspartate) receptors have opposite effects on CREB (cAMP response element binding protein) function, gene regulation and neuron survival. Calcium entry through synaptic NMDA receptors induced CREB activity and brain-derived neurotrophic factor (BDNF) gene expression as strongly as did stimulation of L-type calcium channels. In contrast, calcium entry through extrasynaptic NMDA receptors, triggered by bath glutamate exposure or hypoxic/ischemic conditions, activated a general and dominant CREB shut-off pathway that blocked induction of BDNF expression. Synaptic NMDA receptors have anti-apoptotic activity, whereas stimulation of extrasynaptic NMDA receptors caused loss of mitochondrial membrane potential (an early marker for glutamate-induced neuronal damage) and cell death. Specific blockade of extrasynaptic NMDA receptors may effectively prevent neuron loss following stroke and other neuropathological conditions associated with glutamate toxicity.

Quantitative imaging of glutathione in hippocampal neurons and glia in culture using monochlorobimane

Glutathione (GSH) is a major antioxidant system in the mammalian central nervous system (CNS). Abnormalities of GSH metabolism have been associated with many disorders of the CNS, including Parkinson's, Alzheimer's, and Huntingdon's diseases and ischaemic/reperfusion injury. Investigation of GSH levels in the CNS generally relies on biochemical assays from cultures enriched for different cell types. Because glia influence neuronal metabolism, we have studied cultures in which neurons and glia are cocultured. This approach demands fluorescence imaging to differentiate between the different cell types in the culture, permitted by the use of monochlorobimane (MCB), which reacts with GSH to produce a fluorescent product. We have defined the conditions required to ensure steady-state MCB loading and show the specificity of MCB for GSH through a reaction catalysed by glutathione-S-transferase (GST). [GSH] was consistently higher in glia than in neurons, and [GSH] in both cell types decreased with time in culture. Inhibition of GSH synthesis by buthionine sulfoximine (BSO) caused a greater proportional depletion of GSH in glia than in neurons. The depletion of GSH induced by BSO was significantly greater in cells cultured for >10 days. Furthermore, release of GSH from glia and its breakdown by the ectoenzyme gamma-glutamyltranspeptidase (gammaGT) maintains [GSH] in neurons. In older cultures, inhibition of gammaGT by acivicin caused significant depletion of neuronal GSH. After inhibition of GSH synthesis by BSO, inhibition of the glia-neuron trafficking pathway by acivicin caused widespread neuronal death. Such neurotoxicity was independent of the endogenous glutamate and nitric oxide synthase, suggesting that it is not due to secondary excitotoxicity.

Age-related changes in rat cerebellar basket cells: a quantitative study using unbiased stereological methods

Cortical cerebellar basket cells are stable postmitotic cells; hence, they are liable to endure age-related changes. Since the cerebellum is a vital organ for the postural control, equilibrium and motor coordination, we aimed to determine the quantitative morphological changes in those interneurons with the ageing process, using unbiased techniques. Material from the cerebellar cortex (Crus I and Crus II) was collected from female rats aged 2, 6, 9, 12, 15, 18, 21 and 24 mo (5 animals per each age group), fixed by intracardiac perfusion, and processed for transmission electron microscopy, using conventional techniques. Serial semithin sections were obtained (5 blocks from each rat), enabling the determination of the number-weighted mean nuclear volume (by the nucleator method). On ultrathin sections, 25 cell profiles from each animal were photographed. The volume density of the nucleus, ground substance, mitochondria, Golgi apparatus (Golgi) and dense bodies (DB), and the mean surface density of the rough endoplasmic reticulum (RER) were determined, by point counting, using a morphometric grid. The mean total volumes of the soma and organelles and the mean total surface area of the RER [SN (RER)] were then calculated. The results were analysed with 1-way ANOVA; posthoc pairwise comparisons of group means were performed using the Newman-Keuls test. The relation between age and each of the parameters was studied by regression analysis. Significant age-related changes were observed for the mean volumes of the soma, ground substance, Golgi, DB, and SN (RER). Positive linear trends were found for the mean volumes of the ground substance, Golgi, and DB; a negative linear trend was found for the SN (RER). These results indicate that rat cerebellar basket cells endure important age-related changes. The significant decrease in the SN (RER) may be responsible for a reduction in the rate of protein synthesis. Additionally, it may be implicated in a cascade of events leading to cell damage due to the excitotoxic activity of glutamate, which could interfere in the functioning of the complex cerebellar neuronal network.

Quantitative evaluation of mitochondrial calcium content in rat cortical neurones following a glutamate stimulus

1. Recent observations showed that a mitochondrial Ca2+ increase is necessary for an NMDA receptor stimulus to be toxic to cortical neurones. In an attempt to determine the magnitude of the Ca2+ fluxes involved in this phenomenon, we used carbonylcyanide-p-(trifluoromethoxy)phenylhydrazone (FCCP), a mitochondrial proton gradient uncoupler, to release mitochondrial free calcium ([Ca2+]m) during and following a glutamate stimulus, and magfura-2 to monitor cytoplasmic free calcium ([Ca2+]c). 2. FCCP treatment of previously unstimulated neurones barely changed [Ca2+]c whereas when added after a glutamate stimulus it elevated [Ca2+]c to a much greater extent than did exposure to glutamate, suggesting a very large accumulation of Ca2+ in the mitochondria. 3. Mitochondrial Ca2+ uptake was dependent on glutamate concentration, whereas the changes in the overall quantity of Ca2+ entering the cell, obtained by simultaneously treating neurones with glutamate and FCCP, showed a response that was essentially all-or-none. 4. Mitochondrial Ca2+ uptake was also dependent on the nature and duration of a given stimulus as shown by comparing [Ca2+]m associated with depolarization and treatment with kainate, NMDA or glutamate. Large mitochondrial Ca2+ accumulation only occurred after a glutamate or NMDA stimulus. 5. These studies provide a method of estimating the accumulation of Ca2+ in the mitochondria of neurones, and suggest that millimolar concentrations of Ca2+ may be reached following intense glutamate stimulation. It was shown that substantially more Ca2+ enters neurones following glutamate receptor activation than is reflected by [Ca2+]c increases.

Glutamate regulates the viability of retinal cells in culture

In this study, we show that glutamate regulates the viability of cultured retinal cells upon transient glucose deprivation. At low concentrations (10-100 microM) glutamate decreased MTT [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide] reduction to about 50% of control and decreased intracellular ATP levels (about 4-fold) after transient glucose removal. Under these conditions, the decrease in MTT reduction was associated with the activation of NMDA (N-methyl-D-aspartate) receptors. Upon exposure to high (10 mM) glutamate and transient glucose deprivation, the intracellular levels of glutamate increased. High glutamate significantly counteracted the decrease in MTT reduction and ATP production observed in the presence of low glutamate concentrations. AOAA (aminooxyacetic acid), a non-specific inhibitor of mitochondrial transaminases, enhanced the intracellular glutamate levels, but did not largely affect glutamate-mediated changes in MTT reduction or ATP production. Furthermore, the intracellular levels of pyruvate were not significantly altered, suggesting that changes in ATP production were not due to an increase in glycolysis. Thus, the recovery from glucose deprivation seems to be facilitated in retinal neuronal cells that had been exposed to high glutamate, in comparison with low glutamate, suggesting a role for high glutamate and glucose in maintaining retinal cell function following conditions of glucose scarcity.

Mitochondrial membrane potential and glutamate excitotoxicity in cultured cerebellar granule cells

The relationship between changes in mitochondrial membrane potential (Deltapsi(m)) and the failure of cytoplasmic Ca(2+) homeostasis, delayed Ca(2+)deregulation (DCD), is investigated for cultured rat cerebellar granule cells exposed to glutamate. To interpret the single-cell fluorescence response of cells loaded with tetramethylrhodamine methyl ester (TMRM(+)) or rhodamine-123, we devised and validated a mathematical simulation with well characterized effectors of Deltapsi(m) and plasma membrane potential (Deltapsi(P)). Glutamate usually caused an immediate decrease in Deltapsi(m) of <10 mV, attributable to Ca(2+) accumulation rather than enhanced ATP demand, and these cells continued to generate ATP by oxidative phosphorylation until DCD. Cells for which the mitochondria showed a larger initial depolarization deregulated more rapidly. The mitochondria in a subpopulation of glutamate-exposed cells that failed to extrude Ca(2+) that was released from the matrix after protonophore addition were bioenergetically competent. The onset of DCD during continuous glutamate exposure in the presence or absence of oligomycin was associated with a slowly developing mitochondrial depolarization, but cause and effect could not be established readily. In contrast, the slowly developing mitochondrial depolarization after transient NMDA receptor activation occurs before cytoplasmic free Ca(2+) ([Ca(2+)](c)) has risen to the set point at which mitochondria retain Ca(2+). In the presence of oligomycin no increase in [Ca(2+)](c) occurs during this depolarization. We conclude that transient Ca(2+) loading of mitochondria as a consequence of NMDA receptor activation initiates oxidative damage to both plasma membrane Ca(2+) extrusion pathways and the inhibition of mitochondrial respiration. Depending on experimental conditions, one of these factors becomes rate-limiting and precipitates DCD.

Exploration of the role of reactive oxygen species in glutamate neurotoxicity in rat hippocampal neurones in culture

1. Exposure of hippocampal neurones to glutamate at toxic levels is associated with a profound collapse of mitochondrial potential and deregulation of calcium homeostasis. We have explored the contributions of reactive oxygen species (ROS) to these events, considered to represent the first steps in the progression to cell death. 2. Digital imaging techniques were used to monitor changes in cytosolic Ca2+ concentration ([Ca2+]c; fura-2FF) and mitochondrial potential (Deltapsim; rhodamine 123); rates of ROS generation were assessed using hydroethidium (HEt); and membrane currents were measured with the whole-cell configuration of the patch clamp technique. 3. Inhibitors of lipid peroxidation (trolox plus ascorbate) and scavengers of superoxide or hydrogen peroxide (manganese(III) tetrakis(4-benzoic acid) porphyrin (MnTBAP) and TEMPO plus catalase), had only minimal impact on the mitochondrial depolarisation and the sustained increase in [Ca2+]c during and following a 10 min exposure to glutamate. 4. The antioxidants completely suppressed ROS generated by xanthine with xanthine oxidase. No significant increase in ROS production was detected with HEt during a 10 min glutamate exposure. 5. A combination of antioxidants (TEMPO, catalase, trolox and ascorbate) delayed but did not prevent the glutamate-induced mitochondrial depolarisation and the secondary [Ca2+]c rise. However, this was attributable to a transient inhibition of the NMDA current by the antioxidants. 6. Despite their inability to attenuate the glutamate-induced collapse of Deltapsim and destabilisation of [Ca2+]c homeostasis, the antioxidants conferred significant protection in assays of cell viability at 24 h after a 10 min excitotoxic challenge. The data obtained suggest that antioxidants exert their protective effect against glutamate-induced neuronal death through steps downstream of a sustained increase in [Ca2+]c associated with the collapse of Deltapsi(m).

Intercellular Ca(2+) waves in rat hippocampal slice and dissociated glial-neuron cultures mediated by nitric oxide

Nitric oxide (NO) may participate in cell-cell communication in the brain by generating intercellular Ca(2+) waves. In hippocampal organotypic and dissociated glial-neuron (>80% glia) cultures local applications of aqueous NO induced slowly propagating intercellular Ca(2+) waves. In glial cultures, Ca(2+) waves and Mn(2+) quench of cytosolic fura-2 fluorescence mediated by NO were inhibited by nicardipine, indicating that NO induces Ca(2+) influx in glia which is dihydropyridine-sensitive. As NO treatments also depolarised the plasma membrane potential of glia, the nicardipine-sensitive Ca(2+) influx might be due to the activation of dihydropyridine-sensitive L-type Ca(2+) channels. Both nicardipine-sensitive intercellular Ca(2+) waves and propagating cell depolarisation induced by mechanical stress of individual glia were inhibited by pretreating cultures with either an NO scavenger or N(G)-methyl-L-arginine. Results demonstrate that NO can induce Ca(2+) waves in hippocampal slice cultures, and that Ca(2+) influx coupled to NO-mediated membrane depolarisation might assist in fashioning their spatio-temporal dynamics.

Mitochondria and calcium: from cell signalling to cell death

While a pathway for Ca2+ accumulation into mitochondria has long been established, its functional significance is only now becoming clear in relation to cell physiology and pathophysiology. The observation that mitochondria take up Ca2+ during physiological Ca2+ signalling in a variety of cell types leads to four questions: (i) 'What is the impact of mitochondrial Ca2+ uptake on mitochondrial function?' (ii) 'What is the impact of mitochondrial Ca2+ uptake on Ca2+ signalling?' (iii) 'What are the consequences of impaired mitochondrial Ca2+ uptake for cell function?' and finally (iv) 'What are the consequences of pathological [Ca2+]c signalling for mitochondrial function?' These will be addressed in turn. Thus: (i) accumulation of Ca2+ into mitochondria regulates mitochondrial metabolism and causes a transient depolarisation of mitochondrial membrane potential. (ii) Mitochondria may act as a spatial Ca2+ buffer in many cells, regulating the local Ca2+ concentration in cellular microdomains. This process regulates processes dependent on local cytoplasmic Ca2+ concentration ([Ca2+]c), particularly the flux of Ca2+ through IP3-gated channels of the endoplasmic reticulum (ER) and the channels mediating capacitative Ca2+ influx through the plasma membrane. Consequently, mitochondrial Ca2+ uptake plays a substantial role in shaping [Ca2+]c signals in many cell types. (iii) Impaired mitochondrial Ca2+ uptake alters the spatiotemporal characteristics of cellular [Ca2+]c signalling and downregulates mitochondrial metabolism. (iv) Under pathological conditions of cellular [Ca2+]c overload, particularly in association with oxidative stress, mitochondrial Ca2+ uptake may trigger pathological states that lead to cell death. In the model of glutamate excitotoxicity, microdomains of [Ca2+]c are apparently central, as the pathway to cell death seems to require the local activation of neuronal nitric oxide synthase (nNOS), itself held by scaffolding proteins in close association with the NMDA receptor. Mitochondrial Ca2+ uptake in combination with NO production triggers the collapse of mitochondrial membrane potential, culminating in delayed cell death.

Mitochondria and Ca(2+)in cell physiology and pathophysiology

There is now a consensus that mitochondria take up and accumulate Ca(2+)during physiological [Ca(2+)](c)signalling. This contribution will consider some of the functional consequences of mitochondrial Ca(2+)uptake for cell physiology and pathophysiology. The ability to remove Ca(2+)from local cytosol enables mitochondria to regulate the [Ca(2+)] in microdomains close to IP3-sensitive Ca(2+)-release channels. The [Ca(2+)] sensitivity of these channels means that, by regulating local [Ca(2+)](c), mitochondrial Ca(2+)uptake modulates the rate and extent of propagation of [Ca(2+)](c)waves in a variety of cell types. The coincidence of mitochondrial Ca(2+)uptake with oxidative stress may open the mitochondrial permeability transition pore (mPTP). This is a catastrophic event for the cell that will initiate pathways to cell death either by necrotic or apoptotic pathways. A model is presented in which illumination of an intramitochondrial fluorophore is used to generate oxygen radical species within mitochondria. This causes mitochondrial Ca(2+)loading from SR and triggers mPTP opening. In cardiomyocytes, mPTP opening leads to ATP consumption by the mitochondrial ATPase and so results in ATP depletion, rigor and necrotic cell death. In central mammalian neurons exposed to glutamate, a cellular Ca(2+)overload coincident with NO production also causes loss of mitochondrial potential and cell death, but mPTP involvement has proven more difficult to demonstrate unequivocally.

Mitochondrial membrane potential and glutamate excitotoxicity in cultured cerebellar granule cells

The relationship between changes in mitochondrial membrane potential (Deltapsi(m)) and the failure of cytoplasmic Ca(2+) homeostasis, delayed Ca(2+)deregulation (DCD), is investigated for cultured rat cerebellar granule cells exposed to glutamate. To interpret the single-cell fluorescence response of cells loaded with tetramethylrhodamine methyl ester (TMRM(+)) or rhodamine-123, we devised and validated a mathematical simulation with well characterized effectors of Deltapsi(m) and plasma membrane potential (Deltapsi(P)). Glutamate usually caused an immediate decrease in Deltapsi(m) of <10 mV, attributable to Ca(2+) accumulation rather than enhanced ATP demand, and these cells continued to generate ATP by oxidative phosphorylation until DCD. Cells for which the mitochondria showed a larger initial depolarization deregulated more rapidly. The mitochondria in a subpopulation of glutamate-exposed cells that failed to extrude Ca(2+) that was released from the matrix after protonophore addition were bioenergetically competent. The onset of DCD during continuous glutamate exposure in the presence or absence of oligomycin was associated with a slowly developing mitochondrial depolarization, but cause and effect could not be established readily. In contrast, the slowly developing mitochondrial depolarization after transient NMDA receptor activation occurs before cytoplasmic free Ca(2+) ([Ca(2+)](c)) has risen to the set point at which mitochondria retain Ca(2+). In the presence of oligomycin no increase in [Ca(2+)](c) occurs during this depolarization. We conclude that transient Ca(2+) loading of mitochondria as a consequence of NMDA receptor activation initiates oxidative damage to both plasma membrane Ca(2+) extrusion pathways and the inhibition of mitochondrial respiration. Depending on experimental conditions, one of these factors becomes rate-limiting and precipitates DCD.