Polymerogenic neuroserpin causes mitochondrial alterations and activates NFκB but not the UPR in a neuronal model of neurodegeneration FENIB.

The neurodegenerative condition FENIB (familiar encephalopathy with neuroserpin inclusion bodies) is caused by heterozygous expression of polymerogenic mutant neuroserpin (NS), with polymer deposition within the endoplasmic reticulum (ER) of neurons. We generated transgenic neural progenitor cells (NPCs) from mouse fetal cerebral cortex stably expressing either the control protein GFP or human wild type, polymerogenic G392E or truncated (delta) NS. This cellular model makes it possible to study the toxicity of polymerogenic NS in the appropriated cell type by in vitro differentiation to neurons. Our previous work showed that expression of G392E NS in differentiated NPCs induced an adaptive response through the upregulation of several genes involved in the defence against oxidative stress, and that pharmacological reduction of the antioxidant defences by drug treatments rendered G392E NS neurons more susceptible to apoptosis than control neurons. In this study, we assessed mitochondrial distribution and found a higher percentage of perinuclear localisation in G392E NS neurons, particularly in those containing polymers, a phenotype that was enhanced by glutathione chelation and rescued by antioxidant molecules. Mitochondrial membrane potential and contact sites between mitochondria and the ER were reduced in neurons expressing the G392E mutation. These alterations were associated with a pattern of ER stress that involved the ER overload response but not the unfolded protein response. Our results suggest that intracellular accumulation of NS polymers affects the interaction between the ER and mitochondria, causing mitochondrial alterations that contribute to the neuronal degeneration seen in FENIB patients.

Protection of cerebral microcirculation, mitochondrial function, and electrocortical activity by small-volume resuscitation with terlipressin in a rat model of haemorrhagic shock.

BACKGROUND: During early treatment of haemorrhagic shock, cerebral perfusion pressure can be restored by small-volume resuscitation with vasopressors. Whether this therapy is improved with additional fluid remains unknown. We assessed the value of terlipressin and lactated Ringer's solution (LR) on early recovery of microcirculation, tissue oxygenation, and mitochondrial and electrophysiological function in the rat cerebral cortex. METHODS: Animals treated with LR replacing three times (3LR) the volume bled (n=26), terlipressin (n=27), terlipressin plus 1LR (n=26), 2LR (n=16), or 3LR (n=15) were compared with untreated (n=36) and sham-operated rats (n=17). In vivo confocal microscopy was used to assess cortical capillary perfusion, changes in tissue oxygen concentration, and mitochondrial membrane potential and redox state. Electrophysiological function was assessed by cortical somatosensory evoked potentials, spinal cord dorsum potential, and peripheral electromyography. RESULTS: Compared with sham treatment, haemorrhagic shock reduced the mean (SD) area of perfused vessels [82% (sd 10%) vs 38% (12%); P<0.001] and impaired oxygen concentration, mitochondrial redox state [99% (4%) vs 59% (15%) of baseline; P<0.001], and somatosensory evoked potentials [97% (13%) vs 27% (19%) of baseline]. Administration of terlipressin plus 1LR or 2LR was able to recover these measures, but terlipressin plus 3LR or 3LR alone were not as effective. Spinal cord dorsum potential was preserved in all groups, but no therapy protected electromyographic function. CONCLUSIONS: Resuscitation from haemorrhagic shock using terlipressin with small-volume LR was superior to high-volume LR, with regard to cerebral microcirculation, and mitochondrial and electrophysiological functions.

In Vivo Imaging of Flavoprotein Fluorescence During Hypoxia Reveals the Importance of Direct Arterial Oxygen Supply to Cerebral Cortex Tissue.

Live imaging of mitochondrial function is crucial to understand the important role played by these organelles in a wide range of diseases. The mitochondrial redox potential is a particularly informative measure of mitochondrial function, and can be monitored using the endogenous green fluorescence of oxidized mitochondrial flavoproteins. Here, we have observed flavoprotein fluorescence in the exposed murine cerebral cortex in vivo using confocal imaging; the mitochondrial origin of the signal was confirmed using agents known to manipulate mitochondrial redox potential. The effects of cerebral oxygenation on flavoprotein fluorescence were determined by manipulating the inspired oxygen concentration. We report that flavoprotein fluorescence is sensitive to reductions in cortical oxygenation, such that reductions in inspired oxygen resulted in loss of flavoprotein fluorescence with the exception of a preserved 'halo' of signal in periarterial regions. The findings are consistent with reports that arteries play an important role in supplying oxygen directly to tissue in the cerebral cortex, maintaining mitochondrial function.

The regulation of neuronal mitochondrial metabolism by calcium.

Calcium signalling is fundamental to the function of the nervous system, in association with changes in ionic gradients across the membrane. Although restoring ionic gradients is energetically costly, a rise in intracellular Ca(2+) acts through multiple pathways to increase ATP synthesis, matching energy supply to demand. Increasing cytosolic Ca(2+) stimulates metabolite transfer across the inner mitochondrial membrane through activation of Ca(2+) -regulated mitochondrial carriers, whereas an increase in matrix Ca(2+) stimulates the citric acid cycle and ATP synthase. The aspartate-glutamate exchanger Aralar/AGC1 (Slc25a12), a component of the malate-aspartate shuttle (MAS), is stimulated by modest increases in cytosolic Ca(2+) and upregulates respiration in cortical neurons by enhancing pyruvate supply into mitochondria. Failure to increase respiration in response to small (carbachol) and moderate (K(+) -depolarization) workloads and blunted stimulation of respiration in response to high workloads (veratridine) in Aralar/AGC1 knockout neurons reflect impaired MAS activity and limited mitochondrial pyruvate supply. In response to large workloads (veratridine), acute stimulation of respiration occurs in the absence of MAS through Ca(2+) influx through the mitochondrial calcium uniporter (MCU) and a rise in matrix [Ca(2+) ]. Although the physiological importance of the MCU complex in work-induced stimulation of respiration of CNS neurons is not yet clarified, abnormal mitochondrial Ca(2+) signalling causes pathology. Indeed, loss of function mutations in MICU1, a regulator of MCU complex, are associated with neuromuscular disease. In patient-derived MICU1 deficient fibroblasts, resting matrix Ca(2+) is increased and mitochondria fragmented. Thus, the fine tuning of Ca(2+) signals plays a key role in shaping mitochondrial bioenergetics.

Albumin uptake in OK cells exposed to rotenone: a model for studying the effects of mitochondrial dysfunction on endocytosis in the proximal tubule?

BACKGROUND: The renal proximal tubule (PT) is clinically vulnerable to mitochondrial dysfunction; sub-lethal injury can lead to the Fanconi syndrome, with elevated urinary excretion of low-molecular-weight proteins. As the mechanism that couples mitochondrial dysfunction to impaired PT low-molecular weight protein uptake is unknown, we investigated the effect of respiratory chain (RC) inhibitors on endocytosis of FITC-albumin in PT-derived OK cells. METHODS: Uptake of FITC-albumin was quantified using confocal microscopy. Cytosolic ATP levels were measured in real time using both luciferin/luciferase assays and measurements of free [Mg(2+)]. Reactive oxygen species production was measured using mitosox. RESULTS: RC blockade produced only a small decrease in cytosolic ATP levels and had minimal effect on FITC-albumin uptake. Inhibition of glycolysis caused a much bigger decrease in both cytosolic ATP levels and FITC-albumin endocytosis. Rotenone led to higher rates of reactive oxygen species production than other RC inhibitors. Rotenone also caused widespread structural damage on electron microscopy, which was mimicked by colchicine and prevented by taxol; consistent with inhibition of microtubule polymerisation as the underlying mechanism. CONCLUSIONS: Endocytosis of FITC-albumin is ATP-dependent in OK cells, but the cells are very glycolytic and therefore represent a poor metabolic model of the PT. Rotenone has toxic extra-mitochondrial structural effects.

Mitochondria exert a negative feedback on the propagation of intracellular Ca2+ waves in rat cortical astrocytes.

We have used digital fluorescence imaging techniques to explore the interplay between mitochondrial Ca2+ uptake and physiological Ca2+ signaling in rat cortical astrocytes. A rise in cytosolic Ca2+ ([Ca2+]cyt), resulting from mobilization of ER Ca2+ stores was followed by a rise in mitochondrial Ca2+ ([Ca2+]m, monitored using rhod-2). Whereas [Ca2+]cyt recovered within approximately 1 min, the time to recovery for [Ca2+]m was approximately 30 min. Dissipating the mitochondrial membrane potential (Deltapsim, using the mitochondrial uncoupler carbonyl cyanide p-trifluoromethoxy-phenyl-hydrazone [FCCP] with oligomycin) prevented mitochondrial Ca2+ uptake and slowed the rate of decay of [Ca2+]cyt transients, suggesting that mitochondrial Ca2+ uptake plays a significant role in the clearance of physiological [Ca2+]cyt loads in astrocytes. Ca2+ signals in these cells initiated either by receptor-mediated ER Ca2+ release or mechanical stimulation often consisted of propagating waves (measured using fluo-3). In response to either stimulus, the wave traveled at a mean speed of 22.9 +/- 11.2 micrometer/s (n = 262). This was followed by a wave of mitochondrial depolarization (measured using tetramethylrhodamine ethyl ester [TMRE]), consistent with Ca2+ uptake into mitochondria as the Ca2+ wave traveled across the cell. Collapse of Deltapsim to prevent mitochondrial Ca2+ uptake significantly increased the rate of propagation of the Ca2+ waves by 50%. Taken together, these data suggest that cytosolic Ca2+ buffering by mitochondria provides a potent mechanism to regulate the localized spread of astrocytic Ca2+ signals.

Transient mitochondrial depolarizations reflect focal sarcoplasmic reticular calcium release in single rat cardiomyocytes.

Digital imaging of mitochondrial potential in single rat cardiomyocytes revealed transient depolarizations of mitochondria discretely localized within the cell, a phenomenon that we shall call "flicker." These events were usually highly localized and could be restricted to single mitochondria, but they could also be more widely distributed within the cell. Contractile waves, either spontaneous or in response to depolarization with 50 mM K+, were associated with propagating waves of mitochondrial depolarization, suggesting that propagating calcium waves are associated with mitochondrial calcium uptake and consequent depolarization. Here we demonstrate that the mitochondrial flicker was directly related to the focal release of calcium from sarcoplasmic reticular (SR) calcium stores and consequent uptake of calcium by local mitochondria. Thus, the events were dramatically reduced by (a) depletion of SR calcium stores after long-term incubation in EGTA or thapsigargin (500 nM); (b) buffering intracellular calcium using BAPTA-AM loading; (c) blockade of SR calcium release with ryanodine (30 microM); and (d) blockade of mitochondrial calcium uptake by microinjection of diaminopentane pentammine cobalt (DAPPAC), a novel inhibitor of the mitochondrial calcium uniporter. These observations demonstrate that focal SR calcium release results in calcium microdomains sufficient to promote local mitochondrial calcium uptake, suggesting a tight coupling of calcium signaling between SR release sites and nearby mitochondria.

Interrelationships between astrocyte function, oxidative stress and antioxidant status within the central nervous system.

Astrocytes have, until recently, been thought of as the passive supporting elements of the central nervous system. However, recent developments suggest that these cells actually play a crucial and vital role in the overall physiology of the brain. Astrocytes selectively express a host of cell membrane and nuclear receptors that are responsive to various neuroactive compounds. In addition, the cell membrane has a number of important transporters for these compounds. Direct evidence for the selective co-expression of neurotransmitters, transporters on both neurons and astrocytes, provides additional evidence for metabolic compartmentation within the central nervous system. Oxidative stress as defined by the excessive production of free radicals can alter dramatically the function of the cell. The free radical nitric oxide has attracted a considerable amount of attention recently, due to its role as a physiological second messenger but also because of its neurotoxic potential when produced in excess. We provide, therefore, an in-depth discussion on how this free radical and its metabolites affect the intra and intercellular physiology of the astrocyte(s) and surrounding neurons. Finally, we look at the ways in which astrocytes can counteract the production of free radicals in general by using their antioxidant pathways. The glutathione antioxidant system will be the focus of attention, since astrocytes have an enormous capacity for, and efficiency built into this particular system.

Mitochondria as targets for nitric oxide-induced protection during simulated ischemia and reoxygenation in isolated neonatal cardiomyocytes.

BACKGROUND: As shown previously, exposure to NO donors initiates protective mechanisms in cardiomyocytes that persist after removal of the donor, a form of pharmacological preconditioning. Because NO also affects mitochondrial respiration, we studied the effect of NO on mitochondrial Ca(2+) uptake. METHODS AND RESULTS: Neonatal rat ventricular myocytes in primary culture were exposed to 1 hour of simulated ischemia and 1 hour of reoxygenation (sI/R). Pretreatment with the NO donor S-nitroso-N-acetyl-penicillamine (SNAP) (1 mmol/L for 90 minutes), followed by washing and incubation for 10 to 30 minutes, reduced sI/R-induced cell death to 25.4% compared with control (propidium iodide exclusion assay, P<0.001). Short (10-second) exposures to SNAP reversibly suppressed mitochondrial respiration without a detectable change in mitochondrial potential. In contrast, treatment with SNAP for 90 minutes caused a modest but sustained mitochondrial depolarization, as judged by JC-1 fluorescence. SNAP pretreatment limited cellular Ca(2+) overload during ischemia (fura-2 ratio rose to 226+/-40% versus 516+/-170% of baseline, n=5, P<0.05) and prevented loss of cell membrane integrity during reoxygenation. SNAP pretreatment also significantly reduced the ability of mitochondria to accumulate Ca(2+) in the face of a similar cytosolic Ca(2+) load (peak rhod-2 fluorescence 133+/-4% versus 166+/-7% of baseline at similar fluo-3 levels, P=0.0004, n=52 and 25, respectively). CONCLUSIONS: Pretreatment with an NO donor induces a modest, sustained mitochondrial depolarization and protects cardiomyocytes from sI/R injury. The demonstrated reduction in mitochondrial Ca(2+) uptake possibly reduces cytosolic Ca(2+) overload, providing a likely mechanism for NO-induced protection.

On the involvement of a cyclosporin A sensitive mitochondrial pore in myocardial reperfusion injury.

Mammalian cardiomyocytes may withstand prolonged periods of ischaemia, only to die on reperfusion. We review data that implicate mitochondrial dysfunction as a basis for reperfusion induced cell injury, and present some new evidence that suggests that such a mechanism operates in intact cardiomyocytes. The mitochondrial dysfunction is the consequence of the opening of high conductance pores in the inner mitochondrial membrane, which uncouple mitochondrial oxidative phosphorylation, promoting ATP hydrolysis. The conditions required to open the pores correlate closely to conditions that prevail upon reperfusion of the ischaemic heart: a high [Ca2+]i and Pi, low [ATP], and oxidative stress. Pore opening is suppressed by physiological concentrations of ATP. Pore opening may be prevented by cyclosporin A. Studies in isolated myocytes show that mitochondria become uncoupled after reoxygenation, and that this is associated with the hypercontracture that signals cell death. Cyclosporin A reduces the proportion of hypercontracted myocytes in populations of cells rendered anoxic.

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.

Differential expression of membrane currents in dissociated mouse primary sensory neurons.

The whole cell configuration of the patch clamp technique has been applied to identify the membrane currents expressed by populations of dissociated mouse primary sensory neurons. Three discrete populations of cells were distinguished on the basis of cell size and the array of currents expressed. Group 1 cells (capacitance 10-30 pF) expressed a Na+ current resistant to tetrodotoxin (1 microM) and a prominent, low threshold, inactivating, K+ current sensitive to 4-aminopyridine (IA). A population (53%) of these small cells responded to capsaicin (10 microM) with an inward current, suggesting a functional correlate with nociceptive "C"-cells. The cells of Group 2 (capacitance 55-85 pF) were characterized by the expression of a Na+ current sensitive to tetrodotoxin and a prominent inward current activated by hyperpolarization (IH). They also showed a variant of the A-type K+ current, which was a low threshold, but sustained K+ current, sensitive to dendrotoxin (30 nM). Group 3 cells, of intermediate size (capacitance 30-55 pF) were similar to Group 2 cells, in that they expressed a tetrodotoxin-sensitive Na+ current and (through reduced in amplitude), IH. The most notable feature of Group 3 cells was the expression of a transient, low threshold Ca2+ current. The differential expression of these conductances was reflected in the behaviour of cells under current clamp control. Each group of cells could thus be distinguished by the selective expression of specific ionic conductances which correlated clearly with cell size, suggesting a correlation with well recognised functional differentiation of sensory neurons. The selective expression of specific subsets of membrane channels may provide valuable markers in studying the developmental regulation of phenotype in this population of cells.

Energy metabolism of adult astrocytes in vitro.

In this study we established cultures of astrocytes from the forebrain of the adult rat. The homeostatic regulatory mechanisms of the aerobic and anaerobic pathways of energy metabolism in these cells showed that adult astrocytes express many of the regulatory properties previously demonstrated in neonatal astrocytes. Changes in mitochondrial respiration and ATP production were readily evident upon incubation with the relevant substrates. Inhibition of mitochondrial respiration led to a compensatory increase in anaerobic glycolysis as evidenced by an increased release of lactate. We assessed the role of cytosolic calcium in the regulation of the mitochondrial energy metabolism. Increases in cytosolic calcium concentration in response to ATP or stimulation of mechanical receptors were followed by depolarizations of the mitochondrial membrane potential, whose magnitude reflected the amplitude of the cytosolic calcium response. The changes in mitochondrial membrane potential were largely dependent on the presence of external calcium. These results provide the first evidence of a signalling mechanism in astrocytes by which changes in cytosolic calcium mediate changes in respiration, possibly through mitochondrial calcium uptake and subsequent activation of several mitochondrial dehydrogenases. This signalling pathway would thus ensure that energy demands due to changes in cytosolic calcium concentrations are met by increases in energy production through increases in mitochondrial oxidative phosphorylation.

Mechanisms of intracellular calcium regulation in adult astrocytes.

Microfluorimetric techniques were used to measure changes in intracellular calcium in astrocytes cultured from the forebrain of the adult rat. Application of ATP consistently raised intracellular calcium. The response persisted in the absence of extracellular calcium, but then quickly declined upon repeated agonist application. Thapsigargin abolished responses to nucleotides following depletion of the endoplasmic reticular calcium stores. Calcium release was inhibited by caffeine, but was dramatically increased through inositol phosphate receptor sensitization by the sulphydryl reagent thimerosal. Responses to repeated nucleotide applications resulted in a gradual decline of peak calcium concentrations, suggesting a (post)receptor-mediated desensitization or gradual depletion of the internal calcium stores. Subsequent application of ionomycin suggested intracellular calcium depletion as the relevant mechanism. Depletion of the internal calcium stores with ATP, ionomycin or thapsigargin failed to reveal a calcium influx pathway. These results suggest that the capacitative mechanism of calcium entry does not operate in response to nucleotide receptor activation in these cells, and that the immediate refilling of the internal calcium stores is primarily determined by re-uptake of cytosolic calcium into the endoplasmic reticulum. A complete refilling of this calcium store by extracellular calcium may be a much slower process. Control of these signal transduction pathways is crucial to the maintenance of the calcium/energy homeostasis of the adult astrocyte in the central nervous system.

Biophysical studies of the cellular elements of the rabbit carotid body.

The carotid body is a major sensor of oxygen partial pressure in the arterial blood, and plays a role in the control of respiration. Despite extensive investigation of the structure, the cellular basis of the transduction mechanism remains poorly understood. We have developed a preparation of freshly dissociated cells from the rabbit carotid body, in which two cell types may be identified using morphological criteria. The preparation allows application of the patch clamp technique to characterize the properties of the cells which have otherwise proved difficult to study in situ. Carotid bodies of rabbits were dissociated using a combination of enzymatic and mechanical procedures. The dissociated preparation obtained consisted of clusters of spherical or ovoid cells of 12-15 microns in diameter and a distinct population of spherical cells of 8-10 microns diameter. Electron microscopic techniques were used to identify the cells present in the preparation. Again two populations of cells could be distinguished. A population of cells 10-12 microns in diameter, often found in clusters, possessed the dense-cored vesicles characteristic of Type I cells, while a population of smaller cells (diameter 5-7 microns) had peripherally condensed nuclear chromatin and fine cytoplasmic surface extensions characteristic of Type II cells. Patch clamp study of the cells showed that they represent two electrophysiologically distinct populations. The larger cells, corresponding to Type I cells, were found to be excitable, generating fast, sodium-dependent action potentials that were recorded both in the cell attached and whole cell recording configurations. The smaller Type II cells did not generate action potentials. Voltage clamp study of Type I cells allowed definition of a range of voltage-gated currents. These included an inactivating, tetrodotoxin-sensitive inward sodium current, a high threshold sustained inward calcium current, and outward potassium currents. A component of the outward current showed a dependence on voltage-gated calcium entry, and was blocked by cobalt or cadmium. Of the calcium-dependent current, a component was sensitive to apamin, and the remaining current was blocked by tetraethylammonium. Type II cells showed only a high threshold outward potassium current. These studies have thus revealed an electrophysiological differentiation that parallels the morphological differentiation of the cells of the carotid body. The Type I cell is essentially neuron-like in its properties, while the Type II cell appears to have properties resembling those of glial elements elsewhere in the nervous system.(ABSTRACT TRUNCATED AT 400 WORDS)

Excitation of mouse motoneurones by GABA-mediated primary afferent depolarization.

Observations on the reflex properties of a mouse spinal cord preparation in vitro are reported. The findings show that the synaptically evoked, GABA-mediated, discharge of action potentials in primary afferent fibres, monitored as the dorsal root reflex, may lead to the excitation of motoneurones. Subthreshold, bicuculline-sensitive increases in motoneuronal excitability, followed by prolonged inhibition, may be seen in preparations in which the delayed reflex is not seen. Thus, primary afferent depolarization may both increase motoneuronal excitability and also cause presynaptic inhibition of afferent input.

An intracellular study of the interactions of N-methyl-DL-aspartate with ketamine in the mouse hippocampal slice.

Intracellular recordings were made from dentate and CA1 pyramidal cells of the mouse hippocampal slice preparation. N-methyl-DL-aspartate (NMDLA), quisqualate and kainate and the anaesthetic agent, ketamine, were applied by microelectrophoresis. Excitation by NMDLA but not by the other amino acids, was associated with increased outward rectification. Ketamine had no effect on the resting potential or current/voltage relation of the cells, but selectively antagonised the responses to NMDLA. Action potentials evoked by NMDLA were characteristically broader than those evoked by the other amino acids or by the passage of depolarising current through the electrode.

Primary afferent terminal excitability in the normal and spastic mutant mouse spinal cord.

A microcomputer-based system has been used to apply the technique of excitability testing to the study of the actions of a range of pharmacological agents on the excitability of single primary afferent terminals in the mouse spinal cord in vitro. GABAA analogues all evoked increases in excitability that were bicuculline sensitive. GABA itself also evoked biphasic changes in excitability, or occasionally only suppressed terminal excitability. This latter effect was often enhanced in the presence of bicuculline, and resembled the action of the GABAB agonist, baclofen. The GABAA action could be enhanced by concurrent application of either benzodiazepine, midazolam or flurazepam. Bicuculline alone frequently decreased excitability. This action could be abolished by blocking synaptic activity with a low Ca2+ high Mg2+ superfusate, and was therefore considered to be due to reduction of the tonic action of GABA released at synaptic connections. Comparison of the action of these agents on terminals in the spastic mutant mouse showed an increased sensitivity of the GABA response to the benzodiazepines in mutant animals.

Quality control gone wrong: mitochondria, lysosomal storage disorders and neurodegeneration.

The eukaryotic cell possesses specialized pathways to turn over and degrade redundant proteins and organelles. Each pathway is unique and responsible for degradation of distinctive cytosolic material. The ubiquitin-proteasome system and autophagy (chaperone-mediated, macro, micro and organelle specific) act synergistically to maintain proteostasis. Defects in this equilibrium can be deleterious at cellular and organism level, giving rise to various disease states. Dysfunction of quality control pathways are implicated in neurodegenerative diseases and appear particularly important in Parkinson's disease and the lysosomal storage disorders. Neurodegeneration resulting from impaired degradation of ubiquitinated proteins and α-synuclein is often accompanied by mitochondrial dysfunction. Mitochondria have evolved to control a diverse number of processes, including cellular energy production, calcium signalling and apoptosis, and like every other organelle within the cell, they must be 'recycled.' Failure to do so is potentially lethal as these once indispensible organelles become destructive, leaking reactive oxygen species and activating the intrinsic cell death pathway. This process is paramount in neurons which have an absolute dependence on mitochondrial oxidative phosphorylation as they cannot up-regulate glycolysis. As such, mitochondrial bioenergetic failure can underpin neural death and neurodegenerative disease. In this review, we discuss the links between cellular quality control and neurodegenerative diseases associated with mitochondrial dysfunction, with particular attention to the emerging links between Parkinson's and Gaucher diseases in which defective quality control is a defining factor.

IF1 limits the apoptotic-signalling cascade by preventing mitochondrial remodelling.

Mitochondrial structure has a central role both in energy conversion and in the regulation of cell death. We have previously shown that IF1 protects cells from necrotic cell death and supports cristae structure by promoting the oligomerisation of the F1Fo-ATPsynthase. As IF1 is upregulated in a large proportion of human cancers, we have here explored its contribution to the progression of apoptosis and report that an increased expression of IF1, relative to the F1Fo-ATPsynthase, protects cells from apoptotic death. We show that IF1 expression serves as a checkpoint for the release of Cytochrome c (Cyt c) and hence the completion of the apoptotic program. We show that the progression of apoptosis engages an amplification pathway mediated by: (i) Cyt c-dependent release of ER Ca(2+), (ii) Ca(2+)-dependent recruitment of the GTPase Dynamin-related protein 1 (Drp1), (iii) Bax insertion into the outer mitochondrial membrane and (iv) further release of Cyt c. This pathway is accelerated by suppression of IF1 and delayed by its overexpression. IF1 overexpression is associated with the preservation of mitochondrial morphology and ultrastructure, consistent with a central role for IF1 as a determinant of the inner membrane architecture and with the role of mitochondrial ultrastructure in the regulation of Cyt c release. These data suggest that IF1 is an antiapoptotic and potentially tumorigenic factor and may be a valuable predictor of responsiveness to chemotherapy.