Glutamine transport in cerebellar granule cells in culture

In the present study, uptake of glutamine by rat cerebellar granule cells, a predominantly glutamatergic nerve cell population, has been investigated. Glutamine is taken up by granule cells via at least three transport systems, A, ASC and L. The L-type low affinity system (K_m=2.6 mM) is the major transport system in the absence of Na⁺. The systems A and ASC represent the Na⁺-dependent transport routes, both with almost identical high affinity for glutamine (K_m=0.26 mM). Similar transport systems for glutamine are also found in cerebral cortical neurons, a predominantly GABAergic nerve cell population, and cerebral cortical astrocytes. The glutamine transport properties in granule cells, however, show a series of differences from that of cortical neurons and astrocytes: (1) uptake of glutamine by granule cells is primarily mediated by system A (54%), while contributions by system A in cortical neurons and astrocytes are less than 30%; (2) granule cells exhibit strikingly higher transport efficiency for glutamine (V_max/K_m=20 min⁻¹ for system A as compared to the V_max/K_m ratio of 5 min⁻¹ in cortical neurons and astrocytes), and (3) the initial uptake rates and the steady-state accumulation levels of glutamine are two- to threefold higher in granule cells than that of cortical neurons and astrocytes. These results taken together suggest that in accordance with the important need to replenish the neurotransmitter pool of glutamate, glutamatergic neurons exhibit highly efficient transport systems to accumulate glutamine, one of the major precursors of glutamate.     

Agmatine induces glutamate release and cell death in cultured rat cerebellar granule neurons

We investigated the effect of agmatine on cell viability of rat cerebellar granule neurons in a high-K+ (27.5 mM) medium. Exposure of cultured rat cerebellar granule neurons to agmatine (200-800 microM) resulted in a significant decrease in cell viability. Agmatine-induced neuronal death began to occur 6-12 h after addition, and gradually progressed. The agmatine neurotoxicity was attenuated by N-methyl-D-aspartate (NMDA) receptor antagonists and by enzymatic degradation of L-glutamate with glutamic pyruvic transaminase. Furthermore, a significant increase in extracellular L-glutamate concentration was detected before cell death occurred. In addition, agmatine-induced glutamate release and cell death were both blocked by pretreatment with botulinum toxin C, which is known to specifically inhibit the exocytosis. The agmatine neurotoxicity was not observed when extracellular K+ concentration was lower (10 mM). These results suggest that agmatine induces glutamate release through the exocytosis and thereby causes NMDA receptor-mediated neuronal death in conditions in which extracellular K+ concentrations are elevated.     

Loss of GABAergic neuronal phenotype in primary cerebellar cultures following blockade of glutamate reuptake

Prolonged inhibition of glutamate reuptake by L-trans-pyrrolidine-2,4-dicarboxylate (PDC), a specific glutamate transporter blocker, reduced the number of GABA positive neurons in a primary cerebellar culture by 54%. The disappearance of immunostaining for GABA was gradual and was partially prevented by the N-methyl-D-aspartate (NMDA) receptor blocker, MK-801, and the alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) receptor antagonist, NBQX. Combined blockade of NMDA and AMPA receptors restored the original proportion of GABAergic neurons observed in control cultures. Following the PDC exposure, expression of other GABAergic markers, such as glutamic acid decarboxylase (GAD) and vesicular GABA transporter (VGAT) was also dramatically decreased in an AMPA receptor-dependent manner. Loss of GABA or GAD immunostaining is commonly regarded as a sign of degeneration of GABAergic neurons. However, none of the GABAergic neurons were positive for propidium iodide uptake or showed abnormal nuclear morphology. Based on the above data we conclude that prolonged activation of ionotropic glutamate receptors by endogenously released glutamate was not toxic to cerebellar GABAergic neurons, but lead to the loss of their characteristic neurotransmitter phenotype.     

Regulation of neurotransmitter enzyme by quisqualate subtype glutamate receptors in cultured cerebellar and hippocampal neurons

The possible involvement of ionotropic and metabotropic quisqualate (QA) receptors in neuronal plasticity was studied in cultured glutamtergic cerebellar or hippocampal cells in terms of the specific activity of phosphate-activated glutaminase, an enzyme important in the synthesis of the putative neurotransmitter pool of glutamate. When cerebellar of hippocampal neurons were treated with QA, it elevated the specific activity of glutaminase in a dose-dependent manner. The half-maximal effect was obtained at about 0.1 μM, the maximum increase was at about 1 μM, but levels higher than 10 μM QA produced progressive reduction in glutaminase activity. In contrast, QA had little effects on the activities of lactate dehydrogenase and aspartate aminotransferase and the amount of protein, indicating that the increase in glutaminase was relatively specific. The QA-mediated increase in glutaminase was mimicked by the ionotropic QA receptor agonist -amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA; EC₅₀, about 0.5 μM), but not by the metabotropic QA receptor agonist trans-(±)-1-aino-cyclopentyl-1,3,dicarboxyalte (t-ACPD; up to 0.5 mM). The specific ionotropic QA receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) inhibited QA- and AMPA-mediated increases in glutaminase activity in a dose-dependent manner, whereas other glutamate receptor antagonists, -2-amino-5-phosphonovalerate, γ- -glutamyl aminomethyl sulphonic acid and γ- -glutamyl diethyl ester were ineffective. The elevation of neurotransmitter enzyme was Ca²⁺-dependent. The increase in Ca²⁺ influx essentially through the activation of L-type voltage-operated Ca²⁺ channels, and not the mobilization of internal Ca²⁺ stores, was responsible for these QA receptor-mediated long-term plastic changes in hippocampal and cerebellar neurons.     

阿魏酸钠对培养神经细胞谷氨酸损伤的保护作用

目的 研究当归有效成分阿魏酸钠对谷氨酸引起的离体培养神经细胞损伤的保护作用。方法 运用体外原代胚胎大鼠皮层神经细胞培养技术建立神经细胞损伤的模型，采用台盼兰法测定细胞死亡率，细胞内LDH漏出率评价细胞损伤程度。观察阿魏酸钠对神经细胞死亡率和细胞内LDH漏出率的影响。结果 阿魏酸钠可拮抗谷氨酸介导的神经细胞损伤，神经细胞死亡率明显降低，LDH漏出率减小。结论 阿魏酸钠具有明显的抗缺血性脑损伤的作用。     

Astrocytes protect cultured neurons from degeneration induced by anoxia

Neurons grown in cultures of dissociated brain cells degenerate when exposed to anoxia and deprived of glucose. We have developed culture systems in which neurons can be grown in the presence or absence of astrocytes and have used them to study the influence of astrocytes on the neuronal degeneration induced by anoxia and glucopenia. Cultures were prepared from fetal rat forebrains. Mixed cultures contained neurons (identified by immunocytochemical staining of neuron-specific enolase, NSE) and about an equal number of non-neuronal cells (identified by glial fibrillary acid protein). Pure neuronal cultures were prepared by adding a cytostatic compound (cytosine arabinoside) to the medium. Treated cultures were exposed for 4 h to glucose-free medium and an atmosphere of 95% N₂ and 5% CO₂, whereas control cultures were left in the usual medium containing glucose and in an atmosphere composed of 95% air and 5% CO₂. After an interval of 24 h, cultures were fixed, taken for NSE staining, and the number of surviving neurons was counted. Exposure to anoxia and glucopenia reduced the number of surviving neurons in pure neuronal cultures to 5–10% of control levels. In contrast, in mixed cultures 40–60% of the neurons survived these conditions. Anoxia without glucose deprivation reduced the number of surviving neurons in both types of cultures to the same extent as anoxia combined with glucopenia. Glucose deprivation alone was ineffective. The findings suggest a protective influence of astrocytes on neurons under anoxic conditions. γ-d-Glutamylglycine protected neurons in both types of cultures from anoxia-induced degeneration. However, no evidence was obtained for an involvement of excitatory amino acids in the protective influence of astrocytes.     

磷酸化C—JUN不参与谷氨酸诱导的小脑颗粒神经元凋亡

观察磷酸化 C- JUN与谷氨酸诱导的小脑颗粒神经元凋亡的关系。在培养的小脑颗粒神经元建立谷氨酸凋亡模型 ;采用 MTT法分析细胞存活率 ,相差显微镜观察形态学 ,DNA凝胶电泳法分析细胞凋亡和原位细胞荧光免疫组织化学法检测磷酸化 C- JUN。结果显示 ,谷氨酸诱导大鼠小脑颗粒神经元细胞体积缩小 ,突触断裂、消失 ,DNA电泳呈典型的“梯状”条带 ;谷氨酸处理 2 4 h后细胞存活率为 2 8.6%± 5.2 %。神经元在谷氨酸处理 5,30 min及 1 ,2 ,4,8,1 6和 2 4 h后均未检测到有磷酸化 C- JUN阳性细胞 ,与去极化组 ( 2 5mmol/L KCl)相同。而复极化组 ( 5mmol/L KCl)则在 30 min检测到大量的磷酸化 C- JUN阳性细胞 ,4h荧光最强并持续。处理 4h后 ,40 0倍荧光显微镜下 ,复极化组、去极化组和谷氨酸组的磷酸化 C- JUN阳性细胞数分别为 1 2 4± 1 7,8± 3,5± 3。上述结果提示 ,谷氨酸诱导小脑颗粒神经元凋亡 ,磷酸化 C- JUN不参与谷氨酸诱导的大鼠小脑颗粒神经元凋亡。     

Depolarization or glutamate receptor activation blocks apoptotic cell death of cultured cerebellar granule neurons

Cerebellar granule neurons can be readily maintained in culture if depolarized with high concentrations of K⁺ or subtoxic concentrations of various excitatory amino acids. We now report that these depolarizing stimuli promote cerebellar granule neuron survival by blocking their programmed death via apoptosis. Cerebellar granule neurons maintained in depolarizing conditions and then changed to non-depolarizing conditions, exhibit the morphological and biochemical features of apoptosis, including cytoplasmic blebbing, condensation and aggregation of nuclear chromatin internucleosomal DNA fragmentation. Inhibitors of RNA or protein synthesis greatly attenuate cell death induced by non-depolarizing culture conditions. In contrast, cerebellar granule neurons, when exposed to fresh serum-containing medium or to high concentrations of glutamate, exhibit a delayed-type of neurotoxicity which is non-apoptotic in nature. Given the actions of excitatory amino acid receptor agonists in preventing apoptosis of cultured cerebellar granule neurons, we hypothesize that the functional innervation of postmigratory granule neurons during cerebellar development may prevent further elimination of these neurons by blocking their programmed death.     

Nickel differentially affects NMDA receptor channels in developing cultured rat neurons

Nickel (Ni(2+)) is a transition metal that exerts multiple and complex effects on N-methyl-d-aspartate (NMDA) channels. In both HEK293 cells and Xenopus laevis oocytes expressing recombinant NMDA receptors, Ni(2+) (<100 microM) caused a potentiation of NR2B-containing channels but a voltage-independent inhibition in those containing NR2A. We took advantage of this different response to investigate the developmental switch between NR2B and NR2A subunits in neonatal rat cerebellar granule cells up to 16 days in vitro (DIV) and in rat embryo cortical neurons up to 35 DIV. In both cultures, the effect of Ni(2+) on the NMDA current gradually changed from potentiating to inhibitory with progressing DIV, and the decline of potentiation correlated well with the decrease in sensitivity for the NR2B specific antagonist ifenprodil. Dose-dependent experiments confirmed that Ni(2+) has a different effect in younger cultures with respect to older ones, in agreement with an increase of the percentage of NR2A-containing receptors. The developmental switch occurred within the first 5 DIV in cerebellar granule cells and after 20 DIV in cortical neurons. All these data indicate that Ni(2+) is a suitable marker for the identification of NR2A and NR2B native channel subunits and can be used to trace the development of NMDA receptor composition.     

Modulation by protein kinase C of nitric oxide and cyclic GMP formation in cultured cerebellar granule cells

The possible modulation of nitric oxide (NO) synthase (NOS) activity by protein kinase C (PKC) was investigated in primary cultures of rat cerebellar neurons. Incubation of the cells withl-arginine and nicotinamide-adenine dinucleotide phosphate (NADPH) produced detectable levels of NO, as quantified by photometric assay [0.14 ± 0.03 nmol/h/dish (2.5 × 10⁶ cells)]. The NO producing activity was paralleled by concomitant accumulation of cyclic GMP (cGMP) (0.12 ± 0.02 pmol/dish). Downregulation of PKC by prolonged treatment with phorbol esters or inhibition of the kinase by treatment with staurosporine raised the basal levels of NO and cGMP five fold. When granule cells were incubated in the absence of extracellular Mg²⁺, N-methyl-d-aspartate and, to a lesser extent, glutamate became effective in enhancing NO formation and cGMP accumulation with respect to the control. The NO and cGMP increases induced by the two agonists were almost doubled by treatment of the cells with staurosporine or depletion of PKC. Calphostin C, an inhibitor of the regulatory domain of PKC, was as effective as staurosporine in increasing the formation of NO in both resting and excited cells. These results indicate that downregulation or inhibition of PKC increase NOS activity in cerebellar neurons, and suggest that phosphorylation of NOS by PKC negatively modulates the catalytic activity of the enzyme in these cells.     

Reduced mitochondrial manganese-superoxide dismutase activity exacerbates glutamate toxicity in cultured mouse cortical neurons

Studies of neuronal injury and death after cerebral ischemia and various neurodegenerative diseases have increasingly focused on the interactions between mitochondrial function, reactive oxygen species (ROS) production and glutamate neurotoxicity. Recent findings suggest that increased mitochondrial ROS production precedes neuronal death after glutamate treatment. It is hypothesized that under pathological conditions when mitochondrial function is compromised, extracellular glutamate may exacerbate neuronal injury. In the present study, we focus on the relationship between mitochondrial superoxide production and glutamate neurotoxicity in cultured cortical neurons with normal or reduced levels of manganese-superoxide dismutase (MnSOD) activity. Our results demonstrate that neurons with reduced MnSOD activity are significantly more sensitive to transient exposure to extracellular glutamate. The increased sensitivity of cultured cortical neurons with reduced MnSOD activity is characteristically subject only to treatment by glutamate but not to other glutamate receptor agonists, such as N-methyl- -aspartate, kainate and quisqualate. We suggest that the reduced MnSOD activity in neurons may exacerbate glutamate neurotoxicity via a mechanism independent of receptor activation.     

Activity-dependent survival and enhanced turnover of calcium in cultured rat cerebellar granule neurons

Neurons survive when their activity is maintained. An influential hypothesis on the cellular mechanism underlying this phenomenon is that there is an appropriate range of intracellular Ca²⁺ concentration ([Ca²⁺]i) for survival. The rat cerebellar granule neuron in culture serves as the most often used model system for the analysis of activity-dependent survival, since it does not survive unless an excitant (KCl or glutamate) is added to the culture medium. Against the above-mentioned hypothesis, we found in our previous examination no difference between steady-state [Ca²⁺]i in granule neurons cultured under high KCl (i.e., survival) and low KCl (i.e., death) conditions. In this report, we present the quantitative background of unchanged [Ca²⁺]i between the two culture conditions. Influx of Ca²⁺ due predominantly to L-type voltage-dependent calcium channels was higher in high KCl cultures than in low KCl cultures. At the same time, efflux of Ca²⁺ due to the activity of Ca²⁺/Na⁺ antiport was also higher in high KCl cultures. Additionally, we found that the endocytotic activity was greater in high KCl cultures than in low KCl cultures, as monitored by the rate of uptake of horseradish peroxidase added to medium. Since the uptake was blocked by an internal Ca²⁺ chelator, the increased endocytotic activity in high KCl cultures might be a consequence of the enhanced Ca²⁺ turnover.     

Neuroprotective effects of phenyl-t-butyl-nitrone in gerbil global brain ischemia and in cultured rat cerebellar neurons

We examined the ability of phenyl-t-butyl-nitrone (PBN), an electron spin trapper, to attenuate ischemia-induced forebrain edema and hippocampal CA1 neuronal loss in gerbils, and to protect rat cerebellar neurons in primary culture from glutamate-induced toxicity. PBN, given i.p. at 75 or 150 mg/kg 30 min before ischemia (5 min occlusion), increased survival (at 7 days) of CA1 neurons from 60 +/- 14 (vehicle-treated, n = 17) to 95 +/- 15 (P less than 0.05, n = 15) and 145 +/- 3 (P less than 0.01, n = 15), respectively. When gerbils were treated with PBN (50 mg/kg, i.p.) immediately and 6 h after reperfusion, followed by b.i.d. for an additional 2 days, CA1 neurons survival improved from 35 +/- 9 (vehicle, n = 20, 6 min occlusion) to 106 +/- 17 (P less than 0.01, n = 13). In gerbils exposed to a more severe ischemia (10 min), pretreatment with 150 mg/kg PBN increased the survival of CA1 neurons from 6 +/- 6 (vehicle) to 27 +/- 10 (P less than 0.05, n = 11). Pretreatment with PBN, at 150 mg/kg, reduced forebrain edema (following 15 min ischemia) by 24.7% (P less than 0.01, n = 16). PBN at 50 mg/kg, i.p. had no hypothermic effect and at 75 or 150 mg/kg caused a transient hypothermia. The presence of PBN in the brain was confirmed in microdialysis samples and brain tissue extract using HPLC. In vitro, PBN protected rat cerebellar neurons against 100 microM glutamate-induced toxicity with an EC50 value of 2.7 mM. Our results further support the concept that free radicals contribute to brain injury following ischemia and suggest the potential therapeutic application of electron spin trappers in stroke.     

NMDA receptor activition by residual glutamate in glutamine preparations: a cautionary note regarding weak NMDA receptor agonists

During an investigation of excitatory amino acids on cultured embryonic Xenopus neurons, we observed that commercial preparations of glutamine had weal agonist activity on NMDA-type glutamate receptors. Threshold responses were observed at 100 μM glutamine, and the dose-response relation did not show inflection or saturation at concentrations of up to 10 mM. However, NMDA receptor activation induced by glutamine probably represented activity of residual glutamate because: (a) recrystallization of glutamine reduced residual glutamate levels (measured by HPLC analysis) and NMDA receptor activation by comparable amounts; and (b) glutamate at concentrations close to those predicted to be present in glutamine preparations elicited currents of similar amplitudes. Our data indicate that residual glutamate at levels of less than 0.05% are sufficient to confound studies of weak NMDA receptor agonists.     

Sex steroid effects on extrahypothalamic CNS. I. Estrogen augments neuronal responsiveness to iontophoretically applied glutamate in the cerebellum

The purpose of this study was to test whether 17 beta-estradiol (E2) could alter neuronal activity or responsiveness to iontophoretically applied amino acid neurotransmitters in an area not reported to contain classical E2 receptors. Such a region is the cerebellum, which was selected as a model system for these studies because it has been well characterized electrophysiologically. Extracellular activity of cerebellar Purkinje neurons was recorded from urethane-anesthetized, adult, ovariectomized rats using multibarrel glass micropipets. Spontaneous firing rate and responses of single units to microiontophoretic pulses (10 s pulses every 40 s) of GABA (10-50 nA) or glutamate (GLUT, 3-40 nA) were examined before, during and after iontophoretic (0.25 mM 17 beta-estradiol hemisuccinate) or jugular i.v. (100, 300 or 1000 ng/kg 17 beta-estradiol) administration of E2. Both modes of E2 administration resulted in a significant increase in Purkinje cell excitatory responses to GLUT, independent of the direction of change in spontaneous firing rate. This effect was seen as early as one minute after iontophoretic application of E2 and 10-40 min following i.v. E2. In all cases, recovery to the control level of response was not observed by 2 h following E2 administration. 17 alpha-E2 (300 ng/kg) resulted in a less pronounced, transient increase in GLUT response, while a lower dose (100 ng/kg) did not have any effect. Prior administration of the anti-estrogen tamoxifen did not prevent any of the observed E2 effects. In addition, estrogen-priming did not alter E2-induced potentiation of GLUT responses. In contrast to the effect of E2 on GLUT responsiveness, GABA-mediated inhibition of Purkinje cells was either increased, antagonized or unchanged following E2 application. In summary, this study suggests the hypothesis that circulating levels of E2 may alter neuronal sensitivity to specific neurotransmitter substances within the cerebellar circuitry.     

Cholecystokinin-induced protection of cultured cortical neurons against glutamate neurotoxicity

The effects of cholecystokinin (CCK) on glutamate-induced neurotoxicity were examined using cultured rat cortical neurons. Brief exposure of glutamate followed by an incubation with normal solution for more than 60 min reduced cell viability by 60–70%, compared with control values. Glutamate-induced neurotoxicity was significantly inhibited by MK-801 and ketamine, which are non-competitive blockers of N-methyl-d-aspartate (NMDA) receptors. Octapeptide CCK-8S and CCK-related decapeptide ceruletide at concentrations of 10⁻⁹−10⁻⁷ M dose-dependently reduced glutamate-induced neurotoxicity. A desulfated analog CCK-8NS, which acts selectively as an antagonist of CCK_B receptors, also reduced glutamate neurotoxicity. The neuroprotective effects of CCK were antagonized by L-365260, a CCK_B receptor antagonist, but not by L-364718, a CCK_A receptor antagonist. These results suggest that CCK protects cortical neurons against NMDA receptor-mediated glutamate neurotoxicity via CCK_B receptors.     

Differential cellular distribution of glutamate and glutamine in the rat vestibular endorgans: an immunocytochemical study

The cellular and subcellular localization of glutamate and glutamine in the rat vestibular endorgans was studied by means of postembedding immunocytochemistry. Glutamate immunoreactivity was preferentially distributed in the hair cells, whereas glutamine immunoreactivity was enriched in supporting cells. This points to a metabolic compartmentation similar to that found in glutamatergic nerve terminals and adjacent glial processes in the central nervous system. The present immunocytochemical results are consistent with the existence of a glutamate-glutamine cycle in the vestibular sensory epithelium. Our data are also in agreement with a transmitter role of glutamate in both types of hair cell, although a vesicular enrichment of glutamate in these cells remains to be demonstrated.     

Mastoparan-induced apoptosis of cultured cerebellar granule neurons is initiated by calcium release from intracellular stores

We have recently reported that mastoparan, a peptide toxin isolated from wasp venom, induces apoptosis in cultured cerebellar granule neurons that can be blocked by cholera toxin, an activator of G_s. Measurements of intracellular free calcium concentration ([Ca²⁺]_i) reveal that mastoparan induces a dramatic elevation of [Ca²⁺]_i that is frequently followed by enhanced leakage of fura-2 out of the neurons, suggesting that this rise in [Ca²⁺]_i may be due to a more generalized change in membrane permeability. However, the mastoparan-induced initial elevation of [Ca²⁺]_i is maintained in the absence of extracellular Ca²⁺, suggesting that the rise of [Ca²⁺]_i is from intracellular stores. This conclusion is supported by the observation that depletion of [Ca²⁺]_i stores by pretreatment with either caffeine or thapsigargin attenuates both the rise in [Ca²⁺]_i and cell death induced by mastoparan. Phospholipase C (PLC) inhibitors, neomycin and U73122 block mastoparan-induced increases of [Ca²⁺]_i and protect against neuronal death. Pretreatment with cholera toxin, but not pertussis toxin, reduced the mastoparan-induced rise in [Ca²⁺]_i. Taken together, our data suggest that mastoparan initiates cell death in cerebellar granule neurons by inducing Ca²⁺ release from intracellular stores, probably via activation of PLC and IP₃. A secondary or parallel process results in disruption of plasma membrane integrity and may be ultimately responsible for the death of these neurons by mastoparan.     

Development of spontaneous and glutamate-evoked activity is altered by chronic ethanol in cultured cerebellar Purkinje neurons

The effects of continuous exposure to ethanol on the cytological and physiological development of a central nervous system (CNS) neuron were studied using the cultured Purkinje neuron of the rat cerebellar cortex. Purkinje neurons in fetal rat brain cultures which are established at one day before birth show development comparable to that described in vivo in other studies. In culture, Purkinje neurons progress from immature rounded cells with fine neurites to mature neurons with a branched dendritic structure. These structural changes are accompanied by an increase in the duration and complexity of the excitatory response to glutamate, by transitions in the patterns of spontaneous activity, and by an increase in mean firing rate. Our results demonstrate that chronic exposure to a low concentration of ethanol (90 mg%; 19.5 mM) during development selectively alters the electrophysiological but not the morphological properties of Purkinje neurons. Specifically, ethanol treatment reduces the responsiveness of these neurons to glutamate, delays the expected developmental transitions in patterns of spontaneous activity, and induces increased spontaneous bursting activity, particularly at the stage of dendritic formation. Impairment of responsiveness to glutamate is significant in that it may reflect the compromise by ethanol of a major excitatory pathway in the cerebellar cortex, resulting from the decreased efficacy of glutamatergic input from parallel fibers. In contrast to the results of other studies using adult neurons as a model for the effects of ethanol, our work suggests that the developing CNS neurons does not become tolerant; that is, in the continuing presence of ethanol, it does not express physiological function equivalent to that of the control.     

Cell death in primary cultures of mouse neurons and astrocytes during exposure to and ‘recovery’ from hypoxia, substrate deprivation and simulated ischemia

Effects of hypoxia, substrate deprivationand simulated ischemia (combined hypoxia and substrate deprivation) on cell survival during the insult itself and during a 24 h ‘recovery’ period were studied in primary cultures of mouse astrocytes and in cerebral cortical neuronal-astrocytic co-cultures. Cell death was determined by release of the cytosolic high molecular enzyme lactate dehydrogenase (LDH) as well as morphologically (retention of staining with rhodamine 123 and lack of staining with propidium iodide as an indicator of live cells). Glutamate concentrations were measured in the incubation media at the end of the metabolic insults. Astrocytes were very resistant to hypoxia, but less so to simulated ischemia; under both conditions the glutamate concentrations in the media remained low. Cerebral cortical neurons were almost equally susceptible to damage by hypoxia and by stimulated ischemia, although hypoxia had a faster deleterious effects on some of the neurons and simulated ischemia during a long-term insult (9 h) killed all neurons, whereas a non-negligible neuronal subpopulation survived 9 h of hypoxia. Neuronal cell death after long-term hypoxia (but not after simulated ischemia) was correlated with high concentrations of glutamate in the incubation media. After certain insults, most notably relatively short lasting simulated ischemia (3 h) in neurons (which caused no increased cell death during the insult), there was a large release of LDH during the ‘recovery’ period.