Low-potency glucocorticoid hydrocortisone has similar neurotoxic effects as high-potency glucocorticoid dexamethasone on neurons in the immature chicken cerebellum

High-potency glucocorticoids (GC) are used in the prophylaxis and treatment of neonatal bronchopulmonal dysplasia, but there is concern about side effects on the developing brain. Recently, the low-potency GC hydrocortisone (HC) has been suggested as an alternative to high-potency GC. We compared the neurotoxic effects of HC with the high-potency GC dexamethasone (DEX) in chicken cerebellum. A single dose of GC was injected into the egg at embryonic day 16 and the death of granule neurons in histologic sections of the cerebellar cortex was examined 24 h later. DEX and HC showed a similar dose-dependent induction of morphological apoptosis and caspase-3 activation in the internal granular layer. A doubling of the apoptosis rate compared to the basal rate was seen for the highest dose of DEX (5 mg/kg) and medium dose of HC (1 mg/kg). In cultures of embryonic chicken cerebellar granule cells, DEX and HC increased cell death and induced rapid caspase-3 activation in a similar dose-dependent manner. Transfection of granule cells with a luciferase reporter gene revealed that the dose needed for the activation of gene transcription (classical signalling pathway) with DEX was much lower than for HC. In conclusion, HC does not present itself as a safer drug than DEX in this model. In addition, it appears that DEX and HC induce apoptosis in immature granule neurons via a non-genomic (non-classical) mechanism.

Secretory PLA2-IIA and ROS generation in peripheral mitochondria are critical for neuronal death

In this study the role of mitochondrial secretory PLA2-IIA in glutamate-induced cell death in cultured cerebellar granule neurons has been investigated. Inhibition of secretory PLA2-IIA blocked glutamate-induced cell death. Since PLA2 may generate reactive oxygen species (ROS), we have investigated ROS production, detected as dihydrorhodamine 123 oxidation and nitrotyrosine modifications of proteins, following glutamate treatment in the absence or presence of an inhibitor of secretory PLA2-IIA. There was an increased generation of ROS in both glutamate- and buffer-treated neurons compared to untreated neurons. Scavenging with dihydrorhodamine 123 reduced glutamate-induced death (60%), showing that ROS detected in glutamate-treated neurons were associated with cell death. However, ROS detected in buffer-treated neurons were not associated with toxicity. Glutamate treatment led to ROS production predominantly in peripheral mitochondria, whereas buffer treatment led to ROS production in somal mitochondria. Inhibition of secretory PLA2-IIA (i) reduced the generation of ROS after glutamate treatment, (ii) reduced the ROS production in peripheral mitochondria in glutamate-treated neurons, consistent with the fact that calcium entry through glutamate (NMDA) receptors has a privileged access to peripheral mitochondria, and (iii) did not reduce the generation of ROS after buffer treatment. In conclusion, activation of NMDA receptors induces ROS, which is critical for neuronal death, due to secretory PLA2-IIA associated with peripheral mitochondria.

Preconditioning with estradiol abolishes its neuroprotection in cerebellar neurons

Certain steroids are neuroprotective because they are modulators of neuronal activity or ROS scavengers. We examined neuroprotection following glutamate-induced excitotoxicity in cerebellar granule neuron cultures. 17beta-Estradiol, 17alpha-estradiol (nonestrogenic), or vitamins C+E were equally neuroprotective when coadministered with glutamate, consistent with protection by ROS scavenging. Progesterone protected mainly by an action on GABA-A receptors. Since exogenous antioxidants may influence the level of glutathione, the main endogenous antioxidant in neurons, we investigated if a preconditioning period with the neuroprotectors changed their efficacy as protectors. The neuroprotection by 17beta-estradiol and 17alpha-estradiol, but not progesterone or vitamins C+E, was almost abolished following a preconditioning period of 24h. This reduction was accompanied by an inhibition of the gamma-glutamylcysteine synthetase promoter, and a reduced level of glutathione when preconditioning was combined with the subsequent glutamate exposure. Thus, vitamins C+E and progesterone were more effective long-term neuroprotectors, since preconditioning did not reduce glutathione.

Chicken cerebellar granule neurons rapidly develop excitotoxicity in culture

Rat cerebellar granule cell culture is widely used as a model to study factors that control neuronal differentiation and death (e.g. excitotoxicity). However, a main drawback of this model is its dependence on depolarizing culture condition (25 mM potassium). In addition, it is quite expensive to maintain and requires animal facilities. Here we report that cerebellar granule neuron cultures from chicken may be used as an alternative model to study excitotoxicity. Surprisingly, fetal chicken cells may be grown in a physiological potassium concentration (5 mM potassium). They develop excitotoxicity rapidly in culture (fully developed at 3 days in vitro), and respond to glutamate excitotoxicity similar to rat cultures (ROS production and activation of caspase-3).

Dexamethasone induces cell death which may be blocked by NMDA receptor antagonists but is insensitive to Mg2+ in cerebellar granule neurons

Since dexamethasone may elevate the Ca2+ influx through NMDA receptors, we have investigated mechanisms of dexamethasone toxicity in rat cerebellar granule neurons. Dexamethasone concentrations over 0.1 microM induced cell death that reached about 20% of the death induced by glutamate. Dexamethasone-induced cell death was reduced by more than 80% by the mineralocorticoid antagonist RU 28318 or the NMDA receptor antagonists MK 801 and CGP 39551, whereas RU 28318 rescued only approximately 30% of cells treated with glutamate, indicating that dexamethasone requires NMDA receptors to induce acute neuronal toxicity and that a fraction of the neurons showed this toxicity. Mg2+ reduced the cell death induced by glutamate at potassium concentrations of 1 mM and 5 mM, but not at 25 mM. In contrast, cell death induced by dexamethasone was not significantly reduced by Mg2+ in any of the potassium concentrations. Both glutamate and dexamethasone induced toxicity with translocation of the apoptosis inducer NGFI-B to the mitochondria seen after 30 min-2 h concomitant with activation of apoptosis inducing factor (AIF) and caspase-3. In conclusion, dexamethasone induces a rapid toxicity which is blocked by NMDA receptor antagonists other than Mg2+, and involves mitochondrial apoptosis inducer NGFI-B.

Crosstalk between ERK2 and RXR regulates nuclear import of transcription factor NGFI-B

Transcription factor NGFI-B initiates apoptosis when allowed to translocate to mitochondria. Retinoid-X receptor (RXR), another member of the nuclear receptor family, regulates NGFI-B signaling through heterodimerization and nuclear export. Growth factor EGF activates ERK2, which phosphorylates NGFI-B and determines if NGFI-B is allowed to translocate to mitochondria. In the present study, EGF treatment resulted in an increased nuclear import of NGFI-B. Likewise, active ERK2 resulted in a preferential nuclear localization of NGFI-B. When coexpressed with RXR the nuclear import and nuclear localization induced by active ERK2 were strongly reduced. In the presence of its ligand 9-cis-retinoic acid, RXR no longer inhibited ERK2-induced nuclear import. Thus, RXR serves a permissive role for ERK2-mediated nuclear accumulation of NGFI-B. This finding represents a novel crosstalk between ERK2 and RXR signaling pathways, and explains how two independent inhibitors of apoptosis (EGF and 9-cis-retinoic acid) may cooperate to regulate nuclear targeting of apoptosis inducer NGFI-B.

Cytoplasmic retention of peroxide-activated ERK provides survival in primary cultures of rat hepatocytes

Reactive oxygen species (ROS) are implicated in tissue damage causing primary hepatic dysfunction following ischemia/reperfusion injury and during inflammatory liver diseases. A potential role of extracellular signal-regulated kinase (ERK) as a mediator of survival signals during oxidative stress was investigated in primary cultures of hepatocytes exposed to ROS. Hydrogen peroxide (H(2)O(2)) induced a dose-dependent activation of ERK, which was dependent on MEK activation. The ERK activation pattern was transient compared with the ERK activation seen after stimulation with epidermal growth factor (EGF). Nuclear accumulation of ERK was found after EGF stimulation, but not after H(2)O(2) exposure. A slow import/rapid export mechanism was excluded through the use of leptomycin B, an inhibitor of nuclear export sequence-dependent nuclear export. Reduced survival of hepatocytes during ROS exposure was observed when ERK activation was inhibited. Ribosomal S6 kinase (RSK), a cytoplasmic ERK substrate involved in cell survival, was activated and located in the nucleus of H(2)O(2)-exposed hepatocytes. The activation was abolished when ERK was inhibited with U0126. In conclusion, our results indicate that activity of ERK in the cytoplasm is important for survival during oxidative stress in hepatocytes and that RSK is activated downstream of ERK. Supplementary material for this article can be found on the HEPATOLOGY website (http://www.interscience.wiley.com/jpages/0270-9139/suppmat/index.html).

ERK2 Prohibits Apoptosis-induced Subcellular Translocation of Orphan Nuclear Receptor NGFI-B/TR3

Transcription factor NGFI-B (neuronal growth factor-induced clone B), also called Nur77 or TR3, is an immediate early gene and an orphan member of the nuclear receptor family. The NGFI-B protein also has a function distinct from that of a transcription factor; it translocates to mitochondria to initiate apoptosis. Recently, it was demonstrated that NGFI-B interacts with Bcl-2 by inducing a conformational change in Bcl-2, converting it from protector to a killer. After exposing rat cerebellar granule neurons to glutamate (100 mum, 15 min), NGFI-B translocated to the mitochondria. Growth factors such as the epidermal growth factor activate the MAP kinase ERK, the activity of which may determine whether a cell survives or undergoes apoptosis. In the present study we found that the epidermal growth factor activated ERK2 in cerebellar granule neurons and that this activation prohibited glutamate-induced subcellular translocation of NGFI-B. Likewise, overexpressed active ERK2 resulted in a predominant nuclear localization of green fluorescent protein-tagged NGFI-B. Thus, activation of ERK2 may overcome apoptosis-induced subcellular translocation of NGFI-B. This finding represents a novel and rapid growth factor survival pathway that is independent of gene regulation.

Nuclear receptor and apoptosis initiator NGFI-B is a substrate for kinase ERK2

NGFI-B is an inducible orphan nuclear receptor that initiates apoptosis. Growth factors such as EGF activate the MAP kinase ERK, whose activity may determine if a cell survives or undergoes apoptosis. EGF stimulation of cells leads to phosphorylation of threonine in NGFI-B. Thr-142 of NGFI-B is comprised in a consensus MAP kinase site and was identified as a preferred substrate for ERK2 (but not ERK1) in vitro. These results suggest that NGFI-B may be a molecular target for ERK2 signals and thereby a substrate for crosstalk between a growth factor survival pathway and an inducible regulator of apoptosis.

Re-localization of activated EGF receptor and its signal transducers to multivesicular compartments downstream of early endosomes in response to EGF

The rapid internalization of receptor tyrosine kinases after ligand binding has been assumed to be a negative modulation of signal transduction. However, accumulating data indicate that signal transduction from internalized cell surface receptors also occurs from endosomes. We show that a substantial fraction of tyrosine-phosphorylated epidermal growth factor receptor (EGFR) and Shc, Grb2 and Cbl after internalization relocates from early endosomes to compartments which are negative for the early endosomes, recycling vesicle markers EEA1 and transferrin in EGF-stimulated cells. These compartments contained the multivesicular body and late endosome marker CD63, and the late endosome and lysosome marker LAMP-1, and showed a multivesicular morphology. Subcellular fractionation revealed that activated EGFR, adaptor proteins and activated ERK 1 and 2 were located in EEA1-negative and LAMP-1-positive fractions. Co-immunoprecipitations showed EGFR in complex with both Shc, Grb2 and Cbl. Treatment with the weak base chloroquine or inhibitors of lysosomal enzymes after EGF stimulation induced an accumulation of tyrosine-phosphorylated EGFR and Shc in EEA1-negative and CD63-positive vesicles after a 120-min chase period. This was accompanied by a sustained activation of ERK 1 and 2. These results suggest that EGFR signaling is not spatially restricted to the plasma membrane, primary vesicles and early endosomes, but is continuing from late endocytic trafficking organelles maturing from early endosomes.

Detection of high molecular weight DNA fragments characteristic of early stage apoptosis in cerebellar granule cells exposed to glutamate

In cerebellar granule cells a rapid necrotic cell death has been observed during and immediately after glutamate exposure, followed by a delayed apoptotic type of neuronal death in a subpopulation of the surviving neurons. In some experimental models the DNA fragmentation characteristic of apoptosis is readily detected. In other systems apoptosis may occur only in a limited number of cells, rendering DNA fragmentation undetectable using conventional DNA-staining techniques (e.g., ethidium bromide). We have used a sensitive and non-radioactive method for labeling, detection, and quantification of high molecular weight (HMW) DNA fragments. This method is based on the introduction of thymine dimers into DNA after separation by pulse field gel electrophoresis, followed by detection with thymine dimer specific antibodies. Applying this method to cerebellar granule cells in culture, we detected an increase in the amount of HMW DNA fragments characteristic of apoptosis as early as 4 h after glutamate exposure. The N-methyl-D-aspartic acid (NMDA)-receptor antagonist MK801 protected against the fragmentation, whereas no protection was observed using the non-NMDA-receptor antagonist CNQX.

3-Nitropropionic acid: an astrocyte-sparing neurotoxin in vitro

3-Nitropropionic acid (NPA), an inhibitor of succinate dehydrogenase, is dietary neurotoxin. It is not known if neurons and astrocytes differ in their vulnerability to NPA, therefore, we investigated its toxicity in primary cultures of cerebellar granule cells and astrocytes. NPA inhibited succinate dehydrogenase and tricarboxylic acid cycle activity to the same degree in neurons and astrocytes. Even so NPA acid was 16 times more toxic to neurons than to astrocytes (LC50: 0.7 and 11 mM, respectively). The neurotoxicity of NPA was mediated by NMDA-receptor activation, calcium influx, and formation of reactive oxygen species, as revealed by the protective effect of NMDA-receptor blockade, the accumulation of 45Ca, and the protective effect of N-t-butyl-alpha-phenylnitron (PBN), a scavenger of reactive oxygen species. Cytotoxic concentrations of NPA caused a reduction in the intracellular level of glutathione, which probably contributed to the oxidative damage in both neurons and astrocytes. The relative resistance of astrocytes to NPA appeared to be related to their low tricarboxylic acid cycle activity (5%-10% of that in neurons) and to the inability of NPA to cause astrocytic calcium overload. We conclude that NPA acid predominantly is an astrocyte-sparing neurotoxin.

Infusion of D-cycloserine into temporal-hippocampal areas and restoration of mnemonic function in rats with disrupted glutamatergic temporal systems

Partial transections of the fiber connections between the temporal cortex and the lateral entorhinal cortex at a site of the white matter corresponding to the perirhinal cortex result in impaired visual memory accompanied by reduced concentrations of glutamate in both the temporal cortex and lateral entorhinal cortex. Intraperitoneal administration of the glycinergic receptor agonist D-cycloserine produces complete restoration of memory function, as measured by a brightness discrimination task in rats with temporal cortex/lateral entorhinal cortex transections. The purpose of the present study was to identify in which brain structures the compensatory activity might take place. The results show that infusion of cycloserine into either the temporal cortex or lateral entorhinal cortex fully ameliorated the impairment of temporal cortex/lateral entorhinal cortex lesions, whereas infusion into the hippocampal region caused only a mild improvement of the retention performance. Infusion of cycloserine into the frontal cortex or saline into the temporal cortex or lateral entorhinal cortex had no ameliorating effects on the memory dysfunction of rats bearing temporal cortex/lateral entorhinal cortex transections. It is concluded that the temporal cortex, lateral entorhinal cortex and perirhinal cortex are highly critical in forming visual memory.

Chronic pre-explant blockade of the NMDA receptor affects survival of cerebellar granule cells explanted in vitro

Rat pups were treated with the competitive NMDA antagonist CGP 39551 with daily injections on postnatal days 1 to 8. Cultures of cerebellar granule cells were prepared from these pups as well as from control pups of the same age and body weight. Granule neurons explanted from CGP 39551-treated pups showed a decreased survival, both at short (2 days) or longer (8 days) time in vitro, irrespective of trophic (high K+) or non-trophic (low K+) culture conditions. Granule cells from control or treated animals underwent apoptotic death when shifted from high to low K+ after maturation in vitro and were rescued by lithium (5 mM). Under the same experimental conditions, the block of protein synthesis through cycloheximide only partially protected from apoptotic death granule neurons from control rats, whereas it was totally effective on cultures derived from CGP 39551-treated animals. This suggests that a different balance between apoptotic/necrotic cell death may be the result of the same experimental conditions in the two types of cultures. Finally, the acquisition of excitotoxic sensitivity to glutamate and the protection given by MK-801 were the same in both types of cultures. The present results demonstrate that the previous block of the NMDA receptor negatively affects the subsequent survival of granule cells once they are explanted in vitro, whereas some features related to the maturation of these neurons in vitro are not impaired.

Inhibition of free radical production or free radical scavenging protects from the excitotoxic cell death mediated by glutamate in cultures of cerebellar granule neurons

Glutamate kills sensitive neurons through several steps downstream to receptor activation: increased free Ca2+ levels, activation of various enzymes and accumulation of reactive oxygen species (ROS). We have evaluated in a well established model of neuronal cultures the neuroprotective effects of blocking these mechanisms, either singularly or by combining multiple enzyme inhibition and/or ROS scavenging. In vitro cultures of cerebellar granule cells exposed to a toxic concentration of glutamate (100 microM for 15 min in the absence of Mg2+) combined with several pharmacological treatments. Inhibition of nitric oxide synthase (NOS) and phospholipase A2 (PLA2) were effective in decreasing cell death and the combined treatments showed some degree of additivity. By contrast, inhibition of xanthine oxidase (XO) with allopurinol was uneffective. Antioxidants (in particular vitamin e or vitamin E analogs). protected neurons up to more than 50%. A synergistic effect was demonstrated by the combination of vitamin E and C. On the other hand, antioxidants did not increase the protection granted by enzyme inhibitors, suggesting that they act downstream to NOS and PLA2. In conclusion, NOS and PLA2 activated by Ca2+ influx give rise to reactive oxygen species whose deleterious action can be counteracted either by inhibiting these enzymes or by scavenging the excess of free radicals produced by them. Finally, a moderate protection was obtained by blocking protein synthesis with cycloheximide, suggesting a partial contribution of apoptotic mechanisms to the excitotoxic cell death.

Contributing mechanisms for cysteine excitotoxicity in cultured cerebellar granule cells

Several possible mechanisms for cysteine toxicity on rat cerebellar granule cells were studied and compared with the excitotoxic effect of glutamate. It was shown that the excitotoxic potency of both cysteine and glutamate increased in the presence of elevated concentrations of bicarbonate or increased pH. Pharmacological studies showed that the cysteine toxicity was specifically coupled to the NMDA receptor, whereas the glutamate toxicity was mediated to a smaller extent also by non-NMDA receptors. Treatment of cerebellar granule cells with cysteine led to an increased extracellular level of glutamate. In addition, cysteine sensitized NMDA receptors by reducing disulfide bonds in the receptor to sulfhydryl groups. A mechanism for cysteine excitotoxicity may therefore be formation of cysteine-sensitized NMDA receptors that are stimulated either by cysteine and/or by endogenous glutamate. This mechanism may also be important for the effects observed during regulated physiological release of cysteine.

A microdialysis study in rat brain of dihydrokainate, a glutamate uptake inhibitor

Microdialysis in neostriatum of anaesthetized rats was performed to study effects on amino acid efflux of the glutamate uptake-inhibitor dihydrokainate (DHK). Both basal and K+-evoked (100 mM) efflux of glutamate increased in the presence of DHK. The increase in the basal glutamate efflux occurred at lower DHK concentrations than during K+-depolarization (when the extracellular glutamate concentration was several-fold higher), confirming that DHK is a competitive inhibitor. The increase in basal efflux caused by DHK did not exhibit Ca(2+)-dependency, whereas 50% of the increase in glutamate efflux during K+-depolarization was Ca(2+)-dependent. The Ca(2+)-dependent efflux is related to transmitter release, whereas the Ca(2+)-independent efflux is probably due to metabolic events and/or transport of DHK into cells in exchange for glutamate. Taurine efflux in response to DHK increased both during basal conditions and K+-depolarization, probably secondary to the increase in glutamate concentration, whereas aspartate, GABA, glutamine and alanine effluxes did not change.

Distribution of morphine 6-glucuronide and morphine across the blood-brain barrier in awake, freely moving rats investigated by in vivo microdialysis sampling

Microdialysis was used to sample morphine 6-glucuronide (M6G) and morphine in striatal extracellular fluid after systemic administration in awake, freely moving rats. Morphine or M6G (25-67 mumol/kg) was given subcutaneously, and blood and striatal dialysate were sampled repeatedly during 120 min. Blood samples were obtained by indwelling catheters in the inferior vena cava. Opiates in serum or brain dialysate were analyzed with high-performance liquid chromatography. The functional intactness of the blood-brain barrier was verified by the use of sodium technetate (Na99mTcO4). The fractional penetration into the brain of morphine and M6G was approximately 350- and 90-fold higher than that of Na99mTcO4, respectively, with a relative difference in the transfer of morphine and M6G of about 4. No hydrolysis of M6G to morphine was detected. Striatal dialysate-to-serum ratios of M6G did not differ after 25 or 67 mumol/kg. Serum AUC0-120 min was 10 times higher for M6G than for morphine. This reflects both a smaller volume of distribution (Vd) for M6G and a decreased rate of elimination compared with morphine. The median t1/2 from serum was 36 and 32 min for morphine and M6G, respectively. The striatal dialysate AUC0-120 min of M6G was 2.9 times greater than that of morphine after an equimolar subcutaneous dose. Dialysate tmax was delayed approximately 40 min relatie to serum tmax for both drugs, and the median t1/2 from the dialysate was 82 and 48 min for M6G and morphine, respectively. These results represent direct evidence for the penetration of M6G into the brain after systemic administration to living rats.

Activation of a reporter gene responsive to NGFI-B in cultured neurons and astrocytes

NGFI-B is an immediate early gene and orphan member of the nuclear receptor superfamily. It is induced in several tissues, including brain, and in cultured cerebellar granule cells in response to different stimuli. Since both the induction of its mRNA as well as the level and function of its gene product are under the control of the inducing stimulus, we wanted to study the final outcome of the stimulus, i.e., transcriptional activity, by means of a specific, artificial reporter gene in cultured CNS cells. Cultured cerebellar granule cells and astrocytes were transfected with an NGFI-B responsive reporter gene to study the role of NGFI-B as a transcriptional activator after stimulation of the protein kinase A and C pathways. In both cell types, stimulation of either protein kinase A or C with forskolin (10 microM) or phorbol 12-myristate 13-acetate (0.1 microM), respectively, gave up to fivefold induction of the reporter gene. In the granule cells a combined treatment gave a strong synergistic induction of the reporter gene. The astrocytes showed only weak synergy, indicating cell-specific regulation of the target gene by the two kinases.

Acute and long-term inhibition of agonist-stimulated phosphoinositide hydrolysis by pulse treatment of cerebellar granule cells with TPA

Acute pretreatment (30 min) of primary cultures of cerebellar granule cells with TPA (10 nM) resulted in a decrease in carbachol-and glutamate-stimulated phosphoinositide hydrolysis, but not in basal levels of PI hydrolysis. To investigate the mechanism of TPA action, phospholipase C was assayed in membranes prepared from cerebellar granule cells acutely treated with TPA. TPA had no effect on basal, GTP gamma S-, NaF-, and calcium-stimulated phospholipase C when compared with membranes prepared from vehicle-treated cells. The effects of pulsing with TPA (30-min pulse, 10 nM) on agonist-stimulated PI hydrolysis were studied 1, 3, and 5 or 6 d after TPA treatment. TPA treatment results in a statistically significant decrease in glutamate-stimulated PI hydrolysis, and a slight reduction of carbachol-stimulated PI hydrolysis when compared to temporally matched controls. Measurements in membranes prepared from TPA-treated vs control cells 1, 3, and 5 d after treatment showed that calcium- and NaF-stimulated phospholipase C activity was significantly decreased at all days tested, whereas GTP gamma S-stimulated phospholipase C activity was significantly decreased only at d 3. These data demonstrate differences in the acute vs long-term effects of TPA treatment on agonist-stimulated PH hydrolysis, and suggest that the acute effects may be mediated at the level of the receptor, whereas long-term effects of TPA on PI hydrolysis may be mediated by deficits in effector function.

Changes in evoked potentials and amino acid content during fluorocitrate action studied in rat hippocampal cortex

Fluorocitrate inhibits the glial tricarboxylic acid cycle and thereby the synthesis of glutamine, which is the main precursor for transmitter glutamate. We investigated the possibility that there is a functional correlate to fluorocitrate action by recording evoked field potentials in rat hippocampal slices. The excitatory postsynaptic potential (field-EPSP) was markedly depressed after 7-8 h of fluorocitrate action. The population spike was also reduced, but a major part of the reduction may be the result of weaker synaptic activation rather than reduced excitability of the postsynaptic cells. The activity of thin unmyelinated fibres was only slightly affected. Preceding the changes in the field-EPSP there was a decrease in the glutamine content in the fluorocitrate treated slices relative to controls. Only a small decrease in tissue glutamate was seen concomitantly with the synaptic failure, probably because the transmitter pool of glutamate in those fibres stimulated makes little contribution to the total tissue glutamate.

Evidence using in vivo microdialysis that aminotransferase activities are important in the regulation of the pools of transmitter amino acids

The effect of aminooxyacetic acid (AOAA), an inhibitor of pyridoxal phosphate-dependent enzymes (including the aminotransferases), on the K(+)-evoked release of amino acids was studied during microdialysis of neostriatum in anesthetized rats. K(+)-evoked (100 mM) release of aspartate, glutamate, and GABA was inhibited by 74%, 70%, and 63%, respectively, by 20 mM Mg2+ and are therefore reflecting release from the transmitter pools of these amino acids. Treatment with AOAA decreased the K(+)-evoked release of aspartate, glutamate, and GABA instantly, with a delayed decrease in the efflux of glutamine and alanine, arguing that the synthesis of transmitter amino acids in particular is sensitive to the activity of pyridoxal phosphate-dependent enzymes. Interestingly, GABA release increased severalfold following the initial decrease, probably reflecting inhibition by AOAA on GABA aminotransferase, the enzyme most sensitive to inhibition by AOAA, and responsible for enzymatic inactivation of transmitter GABA.

Memory dysfunction following disruption of glutamergic systems in the temporal region of the rat: effects of agonistic amino acids

It has previously been shown that disruptions of fiber connections between the temporal cortex (TC) and the lateral entorhinal cortex (LEC) in rats result in severely impaired retention of a simultaneous brightness discrimination task. This memory impairment is accompanied by reduced high affinity D-aspartate uptake in both TC and LEC. The purpose of this study was to investigate whether systemic administration of glutamergic agonists might ameliorate the mnemonic dysfunction seen to follow TC/LEC transections. The results from Experiment 1 show that agonists acting selectively at the NMDA receptors (NMDA and glycine) or the quisqualate receptors (AMPA) produced complete amelioration of the memory deficit. Injection of kainic acid only produced a slight improvement of memory. The results from Experiment 2 show that the positive effects of agonists are probably not attributable to peripheral adrenergic mechanisms, because blockade of sympathetic terminal release did not prevent mitigating effect of glycine. The results are discussed in terms of possible central nervous mechanisms interfered with by the various agonists.