Mitochondrial clearance of calcium facilitated by MICU2 controls insulin secretion.

OBJECTIVE: Transport of Ca2+ into pancreatic ß cell mitochondria facilitates nutrient-mediated insulin secretion. However, the underlying mechanism is unclear. Recent establishment of the molecular identity of the mitochondrial Ca2+ uniporter (MCU) and associated proteins allows modification of mitochondrial Ca2+ transport in intact cells. We examined the consequences of deficiency of the accessory protein MICU2 in rat and human insulin-secreting cells and mouse islets. METHODS: siRNA silencing of Micu2 in the INS-1 832/13 and EndoC-ßH1 cell lines was performed; Micu2-/- mice were also studied. Insulin secretion and mechanistic analyses utilizing live confocal imaging to assess mitochondrial function and intracellular Ca2+ dynamics were performed. RESULTS: Silencing of Micu2 abrogated GSIS in the INS-1 832/13 and EndoC-ßH1 cells. The Micu2-/- mice also displayed attenuated GSIS. Mitochondrial Ca2+ uptake declined in MICU2-deficient INS-1 832/13 and EndoC-ßH1 cells in response to high glucose and high K+. MICU2 silencing in INS-1 832/13 cells, presumably through its effects on mitochondrial Ca2+ uptake, perturbed mitochondrial function illustrated by absent mitochondrial membrane hyperpolarization and lowering of the ATP/ADP ratio in response to elevated glucose. Despite the loss of mitochondrial Ca2+ uptake, cytosolic Ca2+ was lower in siMICU2-treated INS-1 832/13 cells in response to high K+. It was hypothesized that Ca2+ accumulated in the submembrane compartment in MICU2-deficient cells, resulting in desensitization of voltage-dependent Ca2+ channels, lowering total cytosolic Ca2+. Upon high K+ stimulation, MICU2-silenced cells showed higher and prolonged increases in submembrane Ca2+ levels. CONCLUSIONS: MICU2 plays a critical role in ß cell mitochondrial Ca2+ uptake. ß cell mitochondria sequestered Ca2+ from the submembrane compartment, preventing desensitization of voltage-dependent Ca2+ channels and facilitating GSIS.

Differential release of amino acids, neuropeptides, and catecholamines from isolated nerve terminals.

We have investigated transmitter release from small and large dense-core vesicles in nerve terminals isolated from guinea pig hippocampus. Small vesicles are found in clusters near the active zone, and large dense-core vesicles are located at ectopic sites. The abilities of Ca2+ channel activation and uniform elevation of Ca2+ concentration (with ionophores) to evoke secretion of representative amino acids, catecholamines, and neuropeptides were compared. For a given increase in Ca2+ concentration, ionophore was less effective than Ca2+ channel activation in releasing amino acids, but not in releasing cholecystokinin-8. Titration of the average Ca2+ concentration showed that the Ca2+ affinity for cholecystokinin-8 secretion was higher than that for amino acids. Catecholamine release showed intermediate behavior. It is concluded that neuropeptide release is triggered by small elevations in the Ca2+ concentration in the bulk cytoplasm, whereas secretion of amino acids requires higher elevations, as produced in the vicinity of Ca2+ channels.

Bioenergetic analysis of cerebellar granule neurons undergoing apoptosis by potassium/serum deprivation.

Apoptosis induced by K+/serum deprivation (low K+) in cerebellar granule neurons has been extensively investigated. The mitochondria play a key role in apoptosis by releasing proapoptotic factors into the cytoplasm, and mitochondrial dysfunction has been proposed as an early or initiating event in this model. To directly test this hypothesis, cellular and mitochondrial bioenergetics were quantified by determining the respiratory parameters of coverslip-attached neurons. While oxidative phosphorylation rate decreased 39-49% in low K+, this was due to decreased cellular ATP demand rather than impaired ATP/ADP exchange or respiratory chain inhibition. From 3 to 5 h in low K+, apoptosis progressed from 13 to 40% despite no appreciable change in respiratory parameters. Changes in steady-state O2-, assessed with dihydroethidium, were seen in granule but not hippocampal neurons. The O2- change correlated with changes in [Ca2+]c, but not mitochondrial respiration. Thus, early mitochondrial dysfunction can be excluded in this common model of neuronal apoptosis.

Mitochondrial membrane potential and neuronal glutamate excitotoxicity: mortality and millivolts.

In the past few years it has become apparent that mitochondria have an essential role in the life and death of neuronal and non-neuronal cells. The central mitochondrial bioenergetic parameter is the protonmotive force, Deltap. Much research has focused on the monitoring of the major component of Deltap, the mitochondrial membrane potential Deltapsim, in intact neurones exposed to excitotoxic stimuli, in the hope of establishing the causal relationships between cell death and mitochondrial dysfunction. Several fluorescent techniques have been used, and this article discusses their merits and pitfalls.

Presynaptic receptors and the control of glutamate exocytosis.

When a typical glutamate-containing neurone fires, an action potential is propagated down the branching axon through more than a thousand varicosities. At each of these release sites the probability that a synaptic vesicle will be exocytosed into the synaptic cleft is individually controlled by means of presynaptic receptors: autoreceptors responding by positive or negative feedback to previously released transmitter, or heteroreceptors under the influence of other neurotransmitters or modulators. The simplest system in which to investigate presynaptic modulation is the isolated nerve terminal or synaptosome; studies with this preparation have revealed a complex interplay of signal-transduction pathways.

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.

Mitochondria control ampa/kainate receptor-induced cytoplasmic calcium deregulation in rat cerebellar granule cells.

Although mitochondria mediate the delayed failure of cytoplasmic Ca(2+) homeostasis [delayed Ca(2+) deregulation (DCD)] in rat cerebellar granule cells resulting from chronic activation of NMDA receptors, their role in AMPA/KA-induced DCD remains to be established. The mitochondrial ATP synthase inhibitor oligomycin protected cells against KA- but not NMDA-evoked DCD. In contrast to NMDA-evoked DCD, no additional protection was afforded by the further addition of rotenone. The effects of KA on cytoplasmic Ca(2+) homeostasis, including the protection afforded by oligomycin, could be reproduced by veratridine. KA exposure induced a partial mitochondrial depolarization that was enhanced by oligomycin, indicating ATP synthase reversal. The nonglycolytic substrates pyruvate and lactate were unable to maintain Ca(2+) homeostasis in the presence of KA. In contrast to NMDA, KA exposure did not cause mitochondrial Ca(2+) loading. The data indicate that Na(+) entry via noninactivating AMPA/KA receptors or voltage-activated Na(+) channels compromises mitochondrial function sufficiently to cause ATP synthase reversal. Oligomycin may protect by preventing the consequent mitochondrial drain of cytoplasmic ATP.

Intrasynaptosomal compartmentation of calcium during depolarization-induced calcium uptake across the plasma membrane.

The distribution of Ca2+ between mitochondrial and non-mitochondrial compartments within intact synaptosomes is investigated during the net Ca2+ uptake induced by plasma membrane depolarization. The steady-state synaptosomal Ca2+ content (5.8 +/- 0.3 nmol/mg protein) is increased by 77% by plasma depolarization induced by veratridine plus ouabain (9.7 +/- 0.6 nmol/mg protein) and by 100% by high K+ (50 mM) (11.0 +/- 0.9 nmol/mg protein). Prior abolition of the mitochondrial membrane potential, and hence inhibition of intrasynaptosomal mitochondrial Ca2+ accumulation, decreased the steady-state Ca2+ accumulation by 40% in both the control and the veratridine-ouabain depolarization, and by almost 60% in the case of high K+ depolarization. Similar values were obtained for the release of Ca2+ from synaptosomes when the mitochondrial membrane was depolarized after a steady state had been attained. Control experiments demonstrated that contaminating free mitochondria were not responsible for the altered Ca2+ accumulation. That the decrease in the Ca2+ accumulation on mitochondrial depolarization corresponds to the extent of the mitochondrial pool was confirmed by rapid synaptosomal disruption with digitonin which gave values of 2.5 +/- 0.5 nmol/mg protein, 4.4 +/- 0.9 nmol/mg protein and 6.9 nmol/mg protein for control or veratridine/ouabain- and high-[K+]-depolarized synaptosomes, respectively. The lesser contribution of intrasynaptosomal mitochondria during veratridine/ouabain-induced depolarization is proposed to be a consequence of raised cytosolic Na+ concentrations activating the mitochondrial Ca2+ efflux pathway. The results demonstrate that intrasynaptosomal mitochondria represent a metabolically responsive Ca2+ pool in situ.

Mitochondria and neuronal glutamate excitotoxicity.

The role of mitochondria in the control of glutamate excitotoxicity is investigated. The response of cultured cerebellar granule cells to continuous glutamate exposure is characterised by a transient elevation in cytoplasmic free calcium concentration followed by decay to a plateau as NMDA receptors partially inactivate. After a variable latent period, a secondary, irreversible increase in calcium occurs (delayed calcium deregulation, DCD) which precedes and predicts subsequent cell death. DCD is not controlled by mitochondrial ATP synthesis since it is unchanged in the presence of the ATP synthase inhibitor oligomycin in cells with active glycolysis. However, mitochondrial depolarisation (and hence inhibition of mitochondrial calcium accumulation) without parallel ATP depletion (oligomycin plus either rotenone or antimycin A) strongly protects the cells against DCD. Glutamate exposure is associated with an increase in the generation of superoxide anion by the cells, but superoxide generation in the absence of mitochondrial calcium accumulation is not neurotoxic. While it is concluded that mitochondrial calcium accumulation plays a critical role in the induction of DCD we can find no evidence for the involvement of the mitochondrial permeability transition.

Aminooxyacetic acid inhibits the malate-aspartate shuttle in isolated nerve terminals and prevents the mitochondria from utilizing glycolytic substrates.

Aminooxyacetate, an inhibitor of pyridoxal-dependent enzymes, is routinely used to inhibit gamma-aminobutyrate metabolism. The bioenergetic effects of the inhibitor on guinea-pig cerebral cortical synaptosomes are investigated. It prevents the reoxidation of cytosolic NADH by the mitochondria by inhibiting the malate-aspartate shuttle, causing a 26 mV negative shift in the cytosolic NAD+/NADH redox potential, an increase in the lactate/pyruvate ratio and an inhibition of the ability of the mitochondria to utilize glycolytic pyruvate. The 3-hydroxybutyrate/acetoacetate ratio decreased significantly, indicating oxidation of the mitochondrial NAD+/NADH couple. The results are consistent with a predominant role of the malate-aspartate shuttle in the reoxidation of cytosolic NADH in isolated nerve terminals. Aminooxyacetate limits respiratory capacity and lowers mitochondrial membrane potential and synaptosomal ATP/ADP ratios to an extent similar to glucose deprivation. Thus, the inhibitor induces a functional 'hypoglycaemia' in nerve terminals and should be used with caution.

Divalent cation modulation of the ionic permeability of the synaptosomal plasma membrane.

Synaptosomes from guinea-pig cerebral cortex reveal two distinct Na+ permeabilities when divalent cations are removed from the incubation. In the presence of Mg2+, Ca2+ chelation by EGTA causes a partial activation of a voltage-dependent tetrodotoxin-sensitive pathway, manifested as a ouabain-sensitive respiratory increase, a partial depolarization of the plasma membrane, and a lowered gradient of gamma-amino[14C]butyrate. In addition there is a hyperpolarization of the mitochondrial membrane potential. When Mg2+ is omitted from the incubation, Ca2+ chelation induces a substantially larger permeability which is only partially sensitive to tetrodotoxin. The tetrodotoxin-insensitive component is not associated with a non-specific permeabilization of the plasma membrane and may be reversed by either Mg2+ or Ca2+.

The mechanism of mitochondrial membrane potential retention following release of cytochrome c in apoptotic GT1-7 neural cells.

The relationship is investigated between mitochondrial membrane potential (Delta Psi(M)), respiration and cytochrome c (cyt c) release in single neural bcl-2 transfected cells (GT1-7bcl-2) or GT1-7puro cells during apoptosis induced by staurosporine (STS). Bcl-2 inhibited the mitochondrial release of cyt c and apoptosis. Three different cell responses to STS were identified in GT1-7puro cells: (i) neither Delta Psi(M) nor cyt c were significantly affected; (ii) a decrease in Delta Psi(M) was accompanied by a complete release of cyt c; or (iii) cyt c release occurred independently of a loss of Delta Psi(M). The endogenous inner membrane proton leak of the in situ mitochondria, monitored by respiration in the presence of oligomycin, was increased by STS by 92% in puro cells, but by only 23% in bcl-2 cells. STS decreased respiratory capacity, in the presence of protonophore, by 31% in puro cells and by 20% in bcl-2 cells. In the absence of STS, oligomycin hyperpolarized mitochondria within both puro and bcl-2-transfected cells, indicating that the organelles were net generators of ATP. However after 15 h exposure to STS oligomycin rapidly collapsed residual mitochondrial polarization in the puro cells, indicating that Delta Psi(M) had been maintained by ATP synthase reversal. bcl-2 cells in contrast, maintained Delta Psi(M) until protonophore was added. These results indicate that the maintenance of Delta Psi(M) following release of cyt c may be a consequence of ATP synthase reversal and cytoplasmic ATP hydrolysis in STS-treated GT1-7 cells.

A ligand-receptor pair that triggers a non-apoptotic form of programmed cell death.

Several receptors that mediate apoptosis have been identified, such as Fas and tumor necrosis factor receptor I. Studies of the signal transduction pathways utilized by these receptors have played an important role in the understanding of apoptosis. Here we report the first ligand-receptor pair-the neuropeptide substance P and its receptor, neurokinin-1 receptor (NK(1)R)-that mediates an alternative, non-apoptotic form of programmed cell death. This pair is widely distributed in the central and peripheral nervous systems, and has been implicated in pain mediation and depression, among other effects. Here we demonstrate that substance P induces a non-apoptotic form of programmed cell death in hippocampal, striatal, and cortical neurons. This cell death requires gene expression, displays a non-apoptotic morphology, and is independent of caspase activation. The same form of cell death is induced by substance P in NK(1)R-transfected human embryonic kidney cells. These results argue that NK(1)R activates a death pathway different than apoptosis, and provide a signal transduction system by which to study an alternative, non-apoptotic cell death program.

Mitochondrial oxidative stress causes chromosomal instability of mouse embryonic fibroblasts.

Reactive oxygen species are an inevitable by-product of mitochondrial respiration. It has been estimated that between 0.4 and 4% of molecular oxygen is converted to the radical superoxide (O2*-) and this level is significantly influenced by the functional status of the mitochondria. It is well established that exogenous oxidative stress and high doses of mitochondrial poisons such as paraquat and carbonyl cyanide 4 (trifluoromethoxy) phenylhydrazone (FCCP) can lead to genomic instability. In this report we show for the first time that endogenous mitochondrial oxidative stress in standard cell culture conditions results in nuclear genomic instability in primary mouse embryonic fibroblasts (MEFs). We show that lack of mitochondrial superoxide dismutase in MEFs leads to a severe increase of double strand breaks, end-to-end fusions, chromosomal translocations, and loss of cell viability and proliferative capacity. Our results predict that endogenous mitochondrial oxidative stress can induce genomic instability, and therefore may have a profound effect in cancer and aging.

Mitochondria in the life and death of neurons.

A prolonged decrease in ATP levels underlies a number of neurodegenerative disorders. Defects in oxidative phosphorylation are associated with a number of neurodegenerative disorders. Mitochondria also play an important role in mediating the initiation of apoptosis.

Mitochondrial dysfunction and glutamate excitotoxicity studied in primary neuronal cultures.

Primary dissociated neuronal cultures have been intensively exploited for the past 15 years as model systems to investigate excitotoxic neuronal degeneration. Even this simplified system contains a complex web of interactions between calcium homeostasis, ATP production and the generation and detoxification of reactive oxygen species. There is increasing realization that the mitochondrion occupies the center stage in these processes. This review covers the normal bioenergetics of the cultured neuron, the ways in which mitochondrial dysfunction impacts upon the ability of the neuron to withstand excitotoxic stress, the nature of the stresses imposed by NMDA receptor activation and possible molecular mechanisms of excitotoxic cell death.

Subsynaptosomal distribution of calcium during aging and 3,4-diaminopyridine treatment.

Since previous studies showed that calcium uptake by synaptosomes from rodents declines with aging, the subsynaptosomal distribution of calcium was determined with the disruption method of Scott et al. Calcium uptake by the mitochondrial (digitonin-resistant) and non-mitochondrial (digitonin-labile) compartments, as well as total uptake, were determined at 2, 5 and 10 min. After a 10 min incubation under resting conditions (5 mM-KCl), total calcium uptake decreased at 10 months (-14.6%) and 30 months (-33.0%) of age; mitochondrial calcium uptake increased by 10 months (+ 11.2%) but declined by 30 months (-17.5%); the non-mitochondrial calcium compartment declined at 10 (-34.7%) and 30 (-43.4%) months when compared to the 3 month old control. With potassium depolarization (31 mM-KCl), total calcium uptake declined from 100% (3 months) to 73.8% (10 months) or 53.0% (30 months); mitochondrial calcium uptake declined from 100% (3 months) to 85.6% (10 months) or 68.4% (30 months); non-mitochondrial calcium uptake decreased at 10 (-34.3%) and 30 (-57.7%) months of age when compared to 3 months (100%). The deficits in calcium homeostasis are not due to changes in synaptosomal volumes or to diminished membrane potentials, as assessed by tetraphenylphosphonium ion accumulation. 3,4-Diaminopyridine partially reversed the alterations in total, mitochondrial and non-mitochondrial calcium uptake by synaptosomes from aged mice.

Chemical modification of the brown fat mitochondrial uncoupling protein with tetranitromethane.

Tetranitromethane reacts with the uncoupling protein of intact brown fat mitochondria. The chloride permeability in the absence of the inhibitory nucleotide GDP is not affected, but the affinity with which GDP binds is decreased, and the coupling between binding of nucleotide and inhibition of chloride permeation is broken.

Pyruvate utilization by synaptosomes is independent of calcium.

The significance of Ca2+ is assessed for the activation of pyruvate by intact nerve terminals (synaptosomes). Titration of glucose-depleted synaptosomes with pyruvate in the presence of either veratridine or uncoupler stimulates respiration in a Ca2+-independent manner. Additionally, the ability of exogenous pyruvate to support the mitochondrial membrane potential in situ is independent of Ca2+. It is concluded that Ca2+ does not regulate pyruvate oxidation in intact synaptosomes.

The regulation of the proton conductance of brown fat mitochondria. Identification of functional and non-functional nucleotide-binding sites.

The binding of purine nucleotides to intact brown fat mitochondria is re-examined. In addition to the previously reported high affinity binding site, a low-affinity site is found, which requires several minutes to saturate. Only the high affinity site is functional in regulating the proton and halide permeabilities of the mitochondria. The low affinity site can introduce errors in the use of nucleotide binding to quantitate the Mr 32000 uncoupling protein unique to these mitochondria.