Dependence of neurones on astrocytes in a coculture system renders neurones sensitive to transforming growth factor beta1-induced glutamate toxicity

Transforming growth factor beta1 (TGF-beta1) has been implicated in formation of astrocyte scars, which prevents axonal regeneration. A coculture system of astrocytes and cerebellar cells was used to investigate possible neurotoxic effects of TGF-beta1. Although not directly neurotoxic, TGF-beta1 was toxic to cerebellar cells in the presence of astrocytes. This toxicity is based on an effect of the cytokine on astrocytes, as conditioned medium from astrocyte cultures treated with TGF-beta1 was more toxic by a similar mechanism. This neurotoxicity was mediated by glutamate present in the culture medium as demonstrated by inhibition by MK-801. Astrocytic ability to metabolise glutamate was compromised by TGF-beta1, as this cytokine increased glutamate concentration. The astrocytes in the coculture system responded to the presence of neurones by secreting neuroprotective interleukin-6, which was partly protective against the TGF-beta1-induced toxicity. In the coculture system, neurones responded to the presence of astrocytes by a reduction in resistance to glutamate toxicity. On addition of TGF-beta1, which compromised astrocytic clearance of glutamate, this reduction in resistance to glutamate toxicity led to a reduction in neuronal survival. These results suggest that when neurones are cocultured with astrocytes they become dependent on astrocytes for survival. This dependence makes neurones susceptible to damage when astrocytes are activated by substances such as TGF-beta1.     

Protection from MPTP-induced neurotoxicity in differentiating mouse N2a neuroblastoma cells

We have shown previously that subcytotoxic concentrations of MPTP (1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine) inhibit axon outgrowth and are associated with increased neurofilament heavy chain (NF-H) phosphorylation in differentiating mouse N2a neuroblastoma cells while higher doses (> 100 microM) cause cell death. In this work we assessed the ability of potential neuroprotective agents to alleviate both MPTP-induced cell death (cytotoxicity) and MPTP-induced NF-H phosphorylation/reduction in axon outgrowth (neurotoxicity) in N2a cells induced to differentiate by dbcAMP. The neurotoxic effects of MPTP occurred in the absence of significant alterations in energy status or mitochondrial membrane potential. The hormone oestradiol (100 microM) reduced the cytotoxic effect of MPTP, but blocked di-butyryl cyclic AMP (dbcAMP)-induced differentiation, i.e. axon outgrowth. Both the cytotoxic and neurotoxic effects of MPTP were reduced by the monoamine oxidase (MAO) inhibitors deprenyl and, to a lesser extent, clorgyline. Alleviation of both neurotoxicity and cytotoxicity was also achieved by conditioned medium derived from rat C6 glioma cells. In contrast, whilst the p38 MAP kinase inhibitor, SB202190, protected cells against MPTP-induced neurotoxicity, it could not maintain cell viability at high MPTP exposures. In each case neuroprotection involved maintenance of the differentiating phenotype linked with attenuation of NF-H hyper-phosphorylation; the latter may represent a mechanism by which neuronal cells can moderate MPTP-induced neurotoxicity. The use of a simplified neuronal cell model, which expresses subtle biochemical changes following neurotoxic insult, could therefore provide a valuable tool for the identification of potential neuroprotective agents.     

Astrocyte Mitochondrial Mechanisms of Ischemic Brain Injury and Neuroprotection

Research on ischemic brain injury has established a central role of mitochondria in neuron death. Astrocytes are also damaged by ischemia, although the participation of mitochondria in their injury is ill defined. As astrocytes are responsible for neuronal metabolic and trophic support, astrocyte dysfunction will compromise postischemic neuronal survival. Ischemic alterations to astrocyte energy metabolism and the uptake and metabolism of the excitatory amino acid transmitter glutamate may be particularly important. Despite the significance of ischemic astrocyte injury, little is known of the mechanisms responsible for astrocyte death and dysfunction. This review focuses on differences between astrocyte and neuronal metabolism and mitochondrial function, and on neuronal-glial interactions. The potential for astrocyte mitochondria to serve as targets of neuroprotective interventions is also discussed.     

Exposure to high glutamate concentration activates aerobic glycolysis but inhibits ATP‐linked respiration in cultured cortical astrocytes

Astrocytes play a key role in removing the synaptically released glutamate from the extracellular space and maintaining the glutamate below neurotoxic level in the brain. However, high concentration of glutamate leads to toxicity in astrocytes, and the underlying mechanisms are unclear. The purpose of this study was to investigate whether energy metabolism disorder, especially impairment of mitochondrial respiration, is involved in the glutamate‐induced gliotoxicity. Exposure to 10‐mM glutamate for 48 h stimulated glycolysis and respiration in astrocytes. However, the increased oxygen consumption was used for proton leak and non‐mitochondrial respiration, but not for oxidative phosphorylation and ATP generation. When the exposure time extended to 72 h, glycolysis was still activated for ATP generation, but the mitochondrial ATP‐linked respiration of astrocytes was reduced. The glutamate‐induced astrocyte damage can be mimicked by the non‐metabolized substrate d ‐aspartate but reversed by the non‐selective glutamate transporter inhibitor TBOA. In addition, the glutamate toxicity can be partially reversed by vitamin E. These findings demonstrate that changes of bioenergetic profile occur in cultured cortical astrocytes exposed to high concentration of glutamate and highlight the role of mitochondria respiration in glutamate‐induced gliotoxicity in cortical astrocytes. Copyright © 2014 John Wiley & Sons, Ltd.     

The role of reactive oxygen species in membrane potential changes in macrophages and astrocytes

Involvement of reactive oxygen species (ROS) in changes of the plasma membrane potential of mouse peritoneal macrophages and astrocytes (U118 cell line) under the action of different agents has been studied. Membrane potential was measured using the voltage-dependent fluorescent oxonol dye DiBAC4(3). Agonists which stimulate macrophages to release ROS (the fMLP peptide and platelet activating factor) caused prolonged hyperpolarization. Experiments with the fluorescent probe 2',7'-dichlorofluorescein diacetate have shown that astrocytes release ROS upon the action of C5a complement anaphylatoxin (but not C3a). The effect of C5a was accompanied with hyperpolarization of the astrocyte plasma membrane. Treatment of the cells with agents which do not induce ROS generation (C3a, lipopolysaccharide, interferon-gamma) depolarized the plasma membrane. Hyperpolarization of both cell types was significantly decreased in the presence of superoxide dismutase (but not catalase). Moreover, the O2- -generating system caused a marked hyperpolarization of both cell types. The data obtained suggest that O2- is involved in the macrophage and astrocyte hyperpolarization response.     

Expression of mutant SOD1 in astrocytes induces functional deficits in motoneuron mitochondria

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disorder characterized by motoneuron degeneration resulting in paralysis and eventual death. ALS is regarded as a motoneuron-specific disorder but increasing evidence indicates non-neuronal cells play a significant role in disease pathogenesis. Although the precise aetiology of ALS remains unclear, mutations in the superoxide dismutase (SOD1) gene are known to account for approximately 20% of familial ALS. We examined the influence of SOD1(G93A) expression in astrocytes on mitochondrial homeostasis in motoneurons in a primary astrocyte : motoneuron co-culture model. SOD1(G93A) expression in astrocytes induced changes in mitochondrial function of both SOD1(G93A) and wild-type motoneurons. In the presence of SOD1(G93A) astrocytes, mitochondrial redox state of both wild-type and SOD1(G93A) motoneurons was more reduced and mitochondrial membrane potential decreased. While intra-mitochondrial calcium levels [Ca(2+)](m) were elevated in SOD1(G93A) motoneurons, changes in mitochondrial function did not correlate with [Ca(2+)](m). Thus, expression of SOD1(G93A) in astrocytes directly alters mitochondrial function even in embryonic motoneurons, irrespective of genotype. These early deficits in mitochondrial function induced by surrounding astrocytes may increase the vulnerability of motoneurons to other neurotoxic mechanisms involved in ALS pathogenesis.     

Effects of estradiol on ischemic factor-induced astrocyte swelling and AQP4 protein abundance

In the early hours of ischemic stroke, cerebral edema forms as Na, Cl, and water are secreted across the blood-brain barrier (BBB) and astrocytes swell. We have shown previously that ischemic factors, including hypoxia, aglycemia, and arginine vasopressin (AVP), stimulate BBB Na-K-Cl cotransporter (NKCC) and Na/H exchanger (NHE) activities and that inhibiting NKCC and/or NHE by intravenous bumetanide and/or HOE-642 reduces edema and infarct in a rat model of ischemic stroke. Estradiol also reduces edema and infarct in this model and abolishes ischemic factor stimulation of BBB NKCC and NHE. There is evidence that NKCC and NHE also participate in ischemia-induced swelling of astrocytes. However, little is known about estradiol effects on astrocyte cell volume. In this study, we evaluated the effects of AVP (100 nM), hypoxia (7.5% O(2)), aglycemia, hypoxia (2%)/aglycemia [oxygen glucose deprivation (OGD)], and estradiol (1-100 nM) on astrocyte cell volume using 3-O-methyl-d-[(3)H]glucose equilibration methods. We found that AVP, hypoxia, aglycemia, and OGD (30 min to 5 h) each significantly increased astrocyte cell volume, and that estradiol (30-180 min) abolished swelling induced by AVP or hypoxia, but not by aglycemia or OGD. Bumetanide and/or HOE-642 also abolished swelling induced by AVP but not aglycemia. Abundance of aquaporin-4, known to participate in ischemia-induced astrocyte swelling, was significantly reduced following 7-day but not 2- or 3-h estradiol exposures. Our findings suggest that hypoxia, aglycemia, and AVP each contribute to ischemia-induced astrocyte swelling, and that the edema-attenuating effects of estradiol include reduction of hypoxia- and AVP-induced astrocyte swelling and also reduction of aquaporin-4 abundance.     

Astrocytes Protect Neurons from Ammonia Toxicity

Ammonia is a neurotoxin that is implicated in the CNS dysfunction associated with hepatic encephalopathy, urea cycle disorders, Reye’s syndrome and other neurological conditions. While in vivo studies suggest that astrocytes are the principal target of ammonia toxicity, recent in vitro investigations suggest that neurons may also be directly affected by ammonia. To further examine the issue of neural cell sensitivity to ammonia, pure rat cortical neuronal cultures, as well as co-cultures of neurons and astrocytes, were exposed to 5 mM NH₄Cl for 48 h. Cultures were examined for morphological changes by light microscopy, measures of cell death, free radical production and changes in the mitochondrial inner membrane potential. Ammonia caused extensive degenerative changes in pure cultured neurons, while such neuronal changes were minor in the co-cultures. Similarly, processes of pure cultured neurons displayed a significant loss of the mitochondrial inner membrane potential, as compared to neurons in co-cultures. Cell death (LDH release) in ammonia-treated neuronal cultures was twice as great as untreated controls, while in co-cultures ammonia did not significantly increase cell death. Free radical production at 3 min was increased (69%, P<0.05) in pure neuronal cultures but not in co-cultures. The neuroprotective effects observed in co-cultures may have been mediated by the astrocyte’s ability to scavenge free radicals, by their detoxification of ammonia and/or by their neurotrophic actions. The neuroprotective action of astrocytes may explain the failure to detect significant pathological changes in neurons in ammonia toxicity in vivo. Special issue dedicated to Dr. Bernd Hamprecht.     

Oxygen and glucose deprivation induces mitochondrial dysfunction and oxidative stress in neurones but not in astrocytes in primary culture

In order to investigate the potential neuroprotective role played by glucose metabolism during brain oxygen deprivation, the susceptibility of cultured neurones and astrocytes to 1 h of oxygen deprivation (hypoxia) or oxygen and glucose deprivation (OGD) was examined. OGD, but not hypoxia, promotes dihydrorhodamine 123 and glutathione oxidation in neurones but not in astrocytes reflecting free radical generation in the former cells. A specific loss of mitochondrial complex-I activity, mitochondrial membrane potential collapse, ATP depletion and necrosis occurred in the OGD neurones, but not in the OGD astrocytes. Furthermore, superoxide anion but not nitric oxide formation was responsible for these effects. OGD decreased neuronal but not astrocytic NADPH concentrations; this was not observed in hypoxia and was independent of superoxide or nitric oxide formation. These results suggest that glucose metabolism would supply NADPH, through the pentose-phosphate pathway, aimed at preventing oxidative stress, mitochondrial damage and neurotoxicity during oxygen deprivation to neural cells.     

Chronic hypoxia potentiates capacitative Ca2+ entry in type-I cortical astrocytes

Prolonged hypoxia exerts profound effects on cell function, and has been associated with increased production of amyloid beta peptides (A beta Ps) of Alzheimer's disease. Here, we have investigated the effects of chronic hypoxia (2.5% O2, 24 h) on capacitative Ca2+ entry (CCE) in primary cultures of rat type-I cortical astrocytes, and compared results with those obtained in astrocytes exposed to A beta Ps. Chronic hypoxia caused a marked enhancement of CCE that was observed after intracellular Ca2+ stores were depleted by bradykinin application or by exposure to thapsigargin (1 microM). Exposure of cells for 24 h to 1 microM A beta P(1-40) did not alter CCE. Enhancement of CCE was not attributable to cell hyperpolarization, as chronically hypoxic cells were significantly depolarized as compared with controls. Mitochondrial inhibition [by FCCP (10 microM) and oligomycin (2.5 microg/mL)] suppressed CCE in all three cell groups, but more importantly there were no significant differences in the magnitude of CCE in the three astrocyte groups under these conditions. Similarly, the antioxidants melatonin and Trolox abolished the enhancement of CCE in hypoxic cells. Our results indicate that chronic hypoxia augments CCE in cortical type-I astrocytes, a finding which is not mimicked by A beta P(1-40) and appears to be dependent on altered mitochondrial function.     

The metabolic enhancer piracetam attenuates mitochondrion-specific endonuclease G translocation and oxidative DNA fragmentation

This study was performed to investigate the involvement of mitochondrion-specific endonuclease G in piracetam (P)-induced protective mechanisms. Studies have shown the antiapoptotic effects of piracetam but the mechanism of action of piracetam is still an enigma. To assess the involvement of endonuclease G in piracetam-induced protective effects, astrocyte glial cells were treated with lipopolysaccharide (LPS) and piracetam. LPS treatment caused significantly decreased viability, mitochondrial activity, oxidative stress, chromatin condensation, and DNA fragmentation, which were attenuated by piracetam cotreatment. Cotreatment of astrocytes with piracetam showed its significantly time-dependent absorption as observed with high-performance liquid chromatography. Astrocytes treated with piracetam alone showed enhanced mitochondrial membrane potential (MMP) in comparison to control astrocytes. However, in LPS-treated cells no significant alteration in MMP was observed in comparison to control cells. Protein and mRNA levels of the terminal executor of the caspase-mediated pathway, caspase-3, were not altered significantly in LPS or LPS + piracetam-treated astrocytes, whereas endonuclease G was significantly translocated to the nucleus in LPS-treated astrocytes. Piracetam cotreatment attenuated the LPS-induced endonuclease G translocation. In conclusion this study indicates that LPS treatment of astrocytes caused decreased viability, oxidative stress, mitochondrial dysfunction, chromatin condensation, DNA damage, and translocation of endonuclease G to the nucleus, which was inhibited by piracetam cotreatment, confirming that the mitochondrion-specific endonuclease G is one of the factors involved in piracetam-induced protective mechanisms.     

Changes in astrocyte mitochondrial function with stress: effects of Bcl-2 family proteins

Mitochondria are central to both apoptotic and necrotic cell death, as well as to normal physiological function. Astrocytes are crucial for neuronal metabolic, antioxidant, and trophic support, as well as normal synaptic function. In the setting of stress, such as during cerebral ischemia, astrocyte dysfunction may compromise the ability of neurons to survive. Despite their central importance, the response of astrocyte mitochondria to stress has not been extensively studied. Limited data already suggest clear differences in the response of neuronal and astrocytic mitochondria to oxygen-glucose deprivation (GD). Prominent mitochondrial alterations during stress that can contribute to cell death include changes in production of reactive oxygen species (ROS) and release of death regulatory and signaling molecules from the intermembrane space. In response to stress mitochondrial respiratory function and membrane potential also change, and these changes appear to depend on cell type. Bcl-2 family proteins are the best studied regulators of cell death, especially apoptosis, and mitochondria are a major site of action for these proteins. Although much data supports the role of Bcl-2 family proteins in the regulation of some of these mitochondrial alterations, this remains an area of active investigation. This mini-review summarizes current knowledge regarding mitochondrial control of cell survival and death in astrocytes and the effects of anti-apoptotic Bcl-2 proteins on astrocyte mitochondrial function.     

Ethyl-nitrosourea transformed astrocytes exhibit mitochondrial membrane hyperpolarization and constrained apoptosis

Recent studies have shown the mitochondria and mitochondrial DNA are altered in gliomas, studied either as primary tissues or in culture. Few studies have been performed which evaluate the mitochondria during the development of glial malignancy. We used an ethyl-nitrosourea (ENU) in vitro model to assess the changes in mitochondrial parameters with progression to astrocyte transformation. When compared to the untreated control cells mitochondrial mass of the ENU treated cells significantly decreased ontologically early with concurrent increase in mitochondrial membrane potential, resulting in hyperpolarization of the mitochondrial membrane. At successive divisions, the degree of spontaneous apoptosis during astrocyte transformation was significantly diminished in the ENU treated cells. With 24 h pre- and co-treatment of ENU cells with citrate, an allosteric inhibitor of phosphofructokinase, the astrocytes still became immortal, but did not manifest any of the mitochondrial changes nor acquire the transformed properties of the ENU treated cells without the inhibition. Indeed, the degree of apoptosis noted in these dually treated cells was increased, associated with a loss of anchorage independence and low density growth. Transformed subclones exposed to citrate after the development of malignant properties also exhibited increased apoptosis, and did not form colonies in low density plating conditions. These results suggest that the development of transformed properties in an ENU model is associated with marked hyperpolarization of mitochondrial membrane potential and diminished spontaneous apoptosis. Exposure to citrate attenuated these mitochondrial changes and in vitro growth properties, with increases in apoptosis. The development of transformed astrocytes involve constraints on apoptosis related to alterations in mitochondrial membrane potential and mass.     

Glutamine in the mechanism of ammonia-induced astrocyte swelling

Brain edema and the subsequent increase in intracranial pressure are the major neurological complications in fulminant hepatic failure (FHF). Brain edema in FHF is predominantly "cytotoxic" due principally to astrocyte swelling. It is generally believed that ammonia plays a key role in this process, although the mechanism by which ammonia brings about such swelling is yet to be defined. It has been postulated that glutamine accumulation in astrocytes subsequent to ammonia detoxification results in increased osmotic forces leading to cell swelling. While the hypothesis is plausible and has gained support, it has never been critically tested. In this study, we examined whether a correlation exists between cellular glutamine levels and the degree of cell swelling in cultured astrocytes exposed to ammonia. Cultured astrocytes derived from rat brain cortices were exposed to ammonia (5 mM) for different time periods and cell swelling was measured. Cultures treated with ammonia for 1-3 days showed a progressive increase in astrocyte cell volume (59-127%). Parallel treatment of astrocyte cultures with ammonia showed a significant increase in cellular glutamine content (60-80%) only at 1-4 h, a time when swelling was absent, while glutamine levels were normal at 1-3 days, a time when peak cell swelling was observed. Thus no direct correlation between cell swelling and glutamine levels was detected. Additionally, acute increase in intracellular levels of glutamine by treatment with the glutaminase inhibitor 6-diazo-5-oxo-L-norleucine (DON) after ammonia exposure also did not result in swelling. On the contrary, DON treatment significantly blocked (66%) ammonia-induced astrocyte swelling at a later time point (24 h), suggesting that some process resulting from glutamine metabolism is responsible for astrocyte swelling. Additionally, ammonia-induced free radical production and induction of the mitochondrial permeability transition (MPT) were significantly blocked by treatment with DON, suggesting a key role of glutamine in the ammonia-induced free radical generation and the MPT. In summary, our findings indicate a lack of direct correlation between the extent of cell swelling and cellular levels of glutamine. While glutamine may not be acting as an osmolyte, we propose that glutamine-mediated oxidative stress and/or the MPT may be responsible for the astrocyte swelling by ammonia.     

Effects of Ranolazine on Astrocytes and Neurons in Primary Culture

Ranolazine (Rn) is an antianginal agent used for the treatment of chronic angina pectoris when angina is not adequately controlled by other drugs. Rn also acts in the central nervous system and it has been proposed for the treatment of pain and epileptic disorders. Under the hypothesis that ranolazine could act as a neuroprotective drug, we studied its effects on astrocytes and neurons in primary culture. We incubated rat astrocytes and neurons in primary cultures for 24 hours with Rn (10⁻⁷, 10⁻⁶ and 10⁻⁵ M). Cell viability and proliferation were measured using trypan blue exclusion assay, MTT conversion assay and LDH release assay. Apoptosis was determined by Caspase 3 activity assay. The effects of Rn on pro-inflammatory mediators IL-β and TNF-α was determined by ELISA technique, and protein expression levels of Smac/Diablo, PPAR-γ, Mn-SOD and Cu/Zn-SOD by western blot technique. In cultured astrocytes, Rn significantly increased cell viability and proliferation at any concentration tested, and decreased LDH leakage, Smac/Diablo expression and Caspase 3 activity indicating less cell death. Rn also increased anti-inflammatory PPAR-γ protein expression and reduced pro-inflammatory proteins IL-1 β and TNFα levels. Furthermore, antioxidant proteins Cu/Zn-SOD and Mn-SOD significantly increased after Rn addition in cultured astrocytes. Conversely, Rn did not exert any effect on cultured neurons. In conclusion, Rn could act as a neuroprotective drug in the central nervous system by promoting astrocyte viability, preventing necrosis and apoptosis, inhibiting inflammatory phenomena and inducing anti-inflammatory and antioxidant agents.     

Activated protein C and thrombin participate in the regulation of astrocyte functions

Protein C anticoagulant system is a multifunctional cofactor-dependent system. In addition to anticoagulant function, activated protein C (APC) also exhibits neuroprotective activity in hypoxia and stroke, but there are no data on potential effects of APC on astrocytes. In the present work we have studied the influence of APC and thrombin on rat astrocytes in primary culture. It was found that thrombin at concentrations above 10 nM (1 U/mL) induced significant activation in the cultured astrocytes resulting in reactive astrogliosis. The cultures exposed to thrombin for 24 h demonstrated a significant increase in proliferation and the S100b protein expression. Thrombin at high concentrations produced visible changes in the cytoskeleton of astrocytes, in particular, an increase in the number of stress fibers in the cultured cells. Moreover, thrombin apparently affected astrocyte migration. Thus, the treatment of serum-starved astrocytes with thrombin resulted in changes in cell monolayer uniformity and formation of “free fields”. APC prevented thrombin-induced proliferation of astrocytes and the S100b protein expression, reducing the parameters under study to the control values. In addition, APC reduced thrombin-induced disorganization of fibrils and formation of “free fields”. The results have demonstrated a new aspect of the protective effect of APC, which suppresses astrocyte activation induced by the proinflammatory effect of thrombin. It suggests a potential application of APC as a regulator of astrogliosis in pathological brain conditions.     

Intranigral infusion of interleukin-1beta activates astrocytes and protects from subsequent 6-hydroxydopamine neurotoxicity

Activation of glial cells is a prevalent response to neuronal damage in brain disease and ageing, with potential neuroprotective and neurotoxic consequences. We were interested in studying the role of glial activation on dopaminergic neurons of the substantia nigra in an animal model of Parkinson's disease. Thus, we evaluated the effect of a pre-existing glial activation on the dopaminergic neuronal death induced by striatal infusion of 6-hydroxydopamine. We established a model of local glial activation by stereotaxic infusion of interleukin-1beta in the substantia nigra of adult rats. Interleukin-1beta (20 ng) induced a marked activation of astrocytes at days 2, 5 and 10, revealed by heat-shock protein 27 and glial fibrillary acid protein immunohistochemistry, but did not affect the microglial markers OX-42 and heat-shock proteins 32 or 47. Intranigral infusion of interleukin-1beta 5 days before a striatal injection of 6-hydroxydopamine significantly protected nigral dopaminergic cell bodies, but not striatal terminals from the 6-hydroxydopamine lesion. Also, in the animals pre-treated with interleukin-1beta, a significant prevention of 6-hydroxydopamine-induced reduction of adjusting steps, but not of 6-hydroxydopamine-induced amphetamine rotations, were observed. These data show the characterization of a novel model of local astroglial activation in the substantia nigra and support the hypothesis of a neuroprotective role of activated astrocytes in Parkinson's disease.     

Exposure of Astrocytes to Hypoxia/Reoxygenation Enhances Expression of Glucose-Regulated Protein 78 Facilitating Astrocyte Release of the Neuroprotective Cytokine Interleukin 6

Abstract: Astrocytes exposed to hypoxia (H) or hypoxia/reoxygenation (H/R) maintain cell viability and display changes in protein biosynthesis. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of metabolically labeled astrocytes exposed to H showed induction of an ≈78-kDa polypeptide that demonstrated sequence identity with glucose-regulated protein (GRP) 78. Cell lysates from H/R astrocytes displayed induction of neuroprotective interleukin (IL) 6, which was present in a high-molecular-weight complex also containing GRP78, suggesting that GRP78 might be functioning as a chaperone during cellular stress consequent on H/R. Introduction of anti-sense oligonucleotide to GRP78 into astrocytes prevented expression of the protein and suppressed H/R-induced astrocyte release of IL-6 by ≈50%. These data indicate that modulation of astrocyte properties during oxygen deprivation results, in part, from intracellular glucose depletion and subsequent expression of GRP78, which sustains generation of neuroprotective IL-6 under the stress of H/R.     

Na-K-Cl Cotransporter-1 in the mechanism of ammonia-induced astrocyte swelling

Brain edema and the consequent increase in intracranial pressure and brain herniation are major complications of acute liver failure (fulminant hepatic failure) and a major cause of death in this condition. Ammonia has been strongly implicated as an important factor, and astrocyte swelling appears to be primarily responsible for the edema. Ammonia is known to cause cell swelling in cultured astrocytes, although the means by which this occurs has not been fully elucidated. A disturbance in one or more of these systems may result in loss of ion homeostasis and cell swelling. In particular, activation of the Na-K-Cl cotransporter (NKCC1) has been shown to be involved in cell swelling in several neurological disorders. We therefore examined the effect of ammonia on NKCC activity and its potential role in the swelling of astrocytes. Cultured astrocytes were exposed to ammonia (NH(4)Cl; 5 mm), and NKCC activity was measured. Ammonia increased NKCC activity at 24 h. Inhibition of this activity by bumetanide diminished ammonia-induced astrocyte swelling. Ammonia also increased total as well as phosphorylated NKCC1. Treatment with cyclohexamide, a potent inhibitor of protein synthesis, diminished NKCC1 protein expression and NKCC activity. Since ammonia is known to induce oxidative/nitrosative stress, and antioxidants and nitric-oxide synthase inhibition diminish astrocyte swelling, we also examined whether ammonia caused oxidation and/or nitration of NKCC1. Cultures exposed to ammonia increased the state of oxidation and nitration of NKCC1, whereas the antioxidants N-nitro-l-arginine methyl ester and uric acid all significantly diminished NKCC activity. These agents also reduced phosphorylated NKCC1 expression. These results suggest that activation of NKCC1 is an important factor in the mediation of astrocyte swelling by ammonia and that such activation appears to be mediated by NKCC1 abundance as well as by its oxidation/nitration and phosphorylation.