tetrodotoxin and Brain-Ischemia

Topics: Animals; Brain; Brain Ischemia; Calcium Channels; Central Nervous System; Down-Regulation; Energy Metabolism; Homeostasis; Humans; Neurons; Neuroprotective Agents; Phosphorylation; Saxitoxin; Sodium; Sodium Channels; Tetrodotoxin

Acidosis accompanying cerebral ischemia activates acid-sensing ion channels (ASIC) causing increases in intracellular calcium concentration ([Ca(2+)]i) and enhanced neuronal death. Experiments were undertaken in rat cortical neurons to explore the effects of ASIC1a activation on ischemia-induced [Ca(2+)]i elevations and whole-cell currents. There was a significant contribution of ASIC1a channels to ischemia-evoked [Ca(2+)]i increases at pH 7.4, suggesting that ASIC1a channels are activated by endogenous protons during ischemia. The combination of ischemia and acidosis resulted in synergistic increases in [Ca(2+)]i and plasma membrane currents relative to acidosis or ischemia alone. ASIC1a inhibitors significantly blunted [Ca(2+)]i increases and a transient current activated by ischemia+acidosis, demonstrating that homomeric ASIC1a channels are involved. However, ASIC1a inhibitors failed to diminish a sustained current activated in response to combined ischemia and acidosis, indicating that acidosis can potentiate ischemia effects through mechanisms other than ASIC1a. The [Ca(2+)]i overload produced by acidosis and ischemia was not blocked by tetrodotoxin, 2-amino-5-phosphonopentanoic acid or nifedipine. Thus, acidosis and activation of ASIC1a channels during ischemia can promote [Ca(2+)]i overload in the absence of neurotransmission, independent of NMDA receptor or L-type voltage-gated Ca(2+) channel activation. Postsynaptic ASIC1a channels play a critical role in ischemia-induced [Ca(2+)]i dysregulation and membrane dysfunction.

Topics: 2-Amino-5-phosphonovalerate; Acid Sensing Ion Channels; Acidosis; Animals; Brain Ischemia; Calcium; Calcium Channels, L-Type; Cerebral Cortex; Nerve Tissue Proteins; Neurons; Nifedipine; Protons; Rats; Receptors, N-Methyl-D-Aspartate; Sodium Channels; Synaptic Transmission; Tetrodotoxin

The RNA binding protein CPEB (cytoplasmic polyadenylation element binding) regulates cytoplasmic polyadenylation and translation in germ cells and the brain. In neurons, CPEB is detected at postsynaptic sites, as well as in the cell body. The related CPEB3 protein also regulates translation in neurons, albeit probably not through polyadenylation; it, as well as CPEB4, is present in dendrites and the cell body. Here, we show that treatment of neurons with ionotropic glutamate receptor agonists causes CPEB4 to accumulate in the nucleus. All CPEB proteins are nucleus-cytoplasm shuttling proteins that are retained in the nucleus in response to calcium-mediated signaling and alpha-calcium/calmodulin-dependent kinase protein II (CaMKII) activity. CPEB2, -3, and -4 have conserved nuclear export signals that are not present in CPEB. CPEB4 is necessary for cell survival and becomes nuclear in response to focal ischemia in vivo and when cultured neurons are deprived of oxygen and glucose. Further analysis indicates that nuclear accumulation of CPEB4 is controlled by the depletion of calcium from the ER, specifically, through the inositol-1,4,5-triphosphate (IP3) receptor, indicating a communication between these organelles in redistributing proteins between subcellular compartments.

Topics: Amino Acid Sequence; Animals; Brain Ischemia; Calcium; Cell Nucleus; Cells, Cultured; Endoplasmic Reticulum; Humans; Molecular Sequence Data; N-Methylaspartate; Neurons; Protein Isoforms; Rats; Receptors, Ionotropic Glutamate; Recombinant Fusion Proteins; RNA-Binding Proteins; Sodium Channel Blockers; Tetrodotoxin

Global ischemia was induced in gerbil by bilateral occlusion of the common carotid arteries for 5 min. Sodium ionophore monensin or sodium channel blocker tetrodotoxin (TTX) was administered at doses of 10 micorg/kg, i.p., 30 min before ischemia induction; the dose was repeated after 22 hr. Subsequently, brain infarct occurred, determined at 24 hr after occlusion. Large, well-demarcated infarcts were observed in both hemispheres, an important observation because it critically influences the interpretation of the data. Because nitric oxide (NO) production is thought to be related to ischemic neuronal damage, we examined increases in Ca(2+) influx, which lead to the activation of nitric oxide synthase (NOS). Then we evaluated the contributions of neuronal NOS, endothelial NOS, and inducible NOS to NO production in brain cryosections. The cytosolic release of apoptogenic molecules like cytochrome c and p53 were confirmed after 24 hr of reflow. TUNEL (terminal deoxynucleotidyl transferase dUTP nick-end labeling) labeling detected the apoptotic cells, which were confirmed in neuron-rich cell populations. After 24 hr, all the ischemic changes were amplified by monensin and significantly attenuated by TTX treatment. Additionally, the nesting behavior and histological outcomes were examined after 7 day of reflow. The neuronal damage in the hippocampal area and significant decrease in nesting scores were observed with monensin treatment and reduced by TTX pretreatment after day 7 of reflow. To our knowledge, this report is the first to highlight the involvement of the voltage-sensitive Na(+) channel in possibly regulating in part NO system and apoptosis in a cytochrome c-dependent manner in global ischemia in the gerbil, and thus warrants further investigation.

Topics: Animals; Apoptosis; Brain; Brain Ischemia; Calcium; Cytochromes c; DNA Fragmentation; Endothelial Cells; Gerbillinae; Hippocampus; In Situ Nick-End Labeling; Ionophores; Male; Monensin; Neurons; Nitric Oxide Synthase; Sodium Channel Blockers; Sodium Channels; Tetrodotoxin; Tumor Suppressor Protein p53

Tolerance to otherwise lethal cerebral ischemia in vivo or to oxygen-glucose deprivation (OGD) in vitro can be induced by prior transient exposure to N-methyl-D-aspartic acid (NMDA): preconditioning in this manner activates extrasynaptic and synaptic NMDA receptors and can require bringing neurons to the "brink of death." We considered if this stressful requirement could be minimized by the stimulation of primarily synaptic NMDA receptors. Subjecting cultured cortical neurons to prolonged elevations in electrical activity induced tolerance to OGD. Specifically, exposing cultures to a K(+)-channel blocker, 4-aminopyridine (20-2500 microm), and a GABA(A) receptor antagonist, bicuculline (50 microm) (4-AP/bic), for 1-2 days resulted in potent tolerance to normally lethal OGD applied up to 3 days later. Preconditioning induced phosphorylation of ERK1/2 and CREB which, along with Ca(2+) spiking and OGD tolerance, was eliminated by tetrodotoxin. Antagonists of NMDA receptors or L-type voltage-gated Ca(2+) channels (L-VGCCs) applied during preconditioning decreased Ca(2+) spiking, phosphorylation of ERK1/2 and CREB, and OGD tolerance more effectively when combined, particularly at the lowest 4-AP concentration. Inhibiting ERK1/2 or Ca(2+)/calmodulin-dependent protein kinases (CaMKs) also reduced Ca(2+) spiking and OGD tolerance. Preconditioning resulted in altered neuronal excitability for up to 3 days following 4-AP/bic washout, based on field potential recordings obtained from neurons cultured on 64-channel multielectrode arrays. Taken together, the data are consistent with action potential-driven co-activation of primarily synaptic NMDA receptors and L-VGCCs, resulting in parallel phosphorylation of ERK1/2 and CREB and involvement of CaMKs, culminating in a potent, prolonged but reversible, OGD-tolerant phenotype.

Topics: Animals; Brain; Brain Ischemia; Calcium; In Vitro Techniques; Ischemic Preconditioning; Microscopy, Fluorescence; Mitogen-Activated Protein Kinase 1; Mitogen-Activated Protein Kinase 3; Models, Biological; Neurons; Phenotype; Rats; Receptors, N-Methyl-D-Aspartate; Synapses; Tetrodotoxin

Sigma receptors are putative targets for neuroprotection following ischemia; however, little is known on their mechanism of action. One of the key components in the demise of neurons following ischemic injury is the disruption of intracellular calcium homeostasis. Fluorometric calcium imaging was used to examine the effects of sigma receptor activation on changes in intracellular calcium concentrations ([Ca(2+)](i)) evoked by in vitro ischemia in cultured cortical neurons from embryonic rats. The sigma receptor agonist, 1,3-di-o-tolyl-guanidine (DTG), was shown to depress [Ca(2+)](i) elevations observed in response to ischemia induced by sodium azide and glucose deprivation. Two sigma receptor antagonists, metaphit [1-(1-(3-isothiocyanatophenyl)-cyclohexyl)-piperidine] and BD-1047 (N-[2-3,4-dichlorophenyl)-ethyl]-N-methyl-2-(dimethylamino)ethylamine), were shown to blunt the ability of DTG to inhibit ischemia-evoked increases in [Ca(2+)](i), revealing that the effects are mediated by activation of sigma receptors and not via the actions of DTG on nonspecific targets such as N-methyl-d-aspartate receptors. DTG inhibition of ischemia-induced increases in [Ca(2+)](i) was mimicked by the sigma-1 receptor-selective agonists, carbetapentane, (+)-pentazocine and PRE-084 [2-(4-morpholinethyl) 1-phenylcyclohexanecarboxylate hydrochloride], but not by the sigma-2-selective agonist, ibogaine, showing that activation of sigma-1 receptors is responsible for the effects. In contrast, DTG, carbetapentane, and ibogaine blocked spontaneous, synchronous calcium transients observed in our preparation at concentrations consistent with sigma receptor-mediated effects, indicating that both sigma-1 and sigma-2 receptors regulate events that affect [Ca(2+)](i) in cortical neurons. Our studies show that activation of sigma receptors can ameliorate [Ca(2+)](i) dysregulation associated with ischemia in cortical neurons and, thus, identify one of the mechanisms by which these receptors may exert their neuroprotective properties.

Topics: Analgesics, Opioid; Animals; Brain Ischemia; Calcium; Calcium Signaling; Cerebral Cortex; Cyclopentanes; Cytophotometry; Enzyme Inhibitors; Ethylenediamines; Female; Guanidines; Morpholines; Neurons; Pentazocine; Phencyclidine; Pregnancy; Rats; Receptors, N-Methyl-D-Aspartate; Receptors, sigma; Sigma-1 Receptor; Sodium Azide; Sodium Channel Agonists; Tetrodotoxin

Glutamate extracellular accumulation is an early event in brain ischemia triggering excitotoxic neuron damage. We have investigated how to control the glutamate efflux from human cerebrocortical slices superfused in conditions simulating an acute ischemic insult (oxygen and glucose deprivation). The efflux of previously accumulated [3H]D-aspartate or endogenous glutamate increased starting 18 min after exposure to ischemia and returned almost to basal values in 6 min reperfusion with standard medium. Superfusion with Ca2+-free, EGTA (0.5 mM)-containing medium or with medium containing tetrodotoxin (TTX; 0.5 microM) inhibited the ischemia (24 min)-evoked [3H]D-aspartate efflux by about 50% and 65%, respectively. The ischemia (24 or 36 min)-evoked efflux of [3H]D-aspartate or endogenous glutamate was reduced at least 40% by the adenosine A(2A) receptor antagonist SCH 58261 (1 microM); the compound was effective when added up to 15 min after exposure to ischemia. No effect of SCH 58261 on the ischemia-evoked [3H]D-aspartate was found in Ca2+-free, EGTA-containing medium. To conclude, a significant component of the ischemia-evoked glutamate efflux in human cerebrocortical slices seems to occur by a vesicular-like mechanism. Endogenously released adenosine is likely to activate A(2A) receptors that enhance vesicular-like glutamate release during ischemia; A(2A) receptor antagonists would deserve consideration for their neuroprotective potential.

Topics: Adenosine A2 Receptor Antagonists; Adult; Aged; Anesthetics, Local; Aspartic Acid; Brain Ischemia; Calcium; Cerebral Cortex; Female; Glucose; Glutamic Acid; Humans; In Vitro Techniques; Male; Middle Aged; Neuroprotective Agents; Pyrimidines; Reperfusion Injury; Synaptic Vesicles; Tetrodotoxin; Triazoles

We investigated the role of the Ca(v)2.3 (alpha1E) channel in ischemic neuronal injury using Ca(v)2.3 mutant mice. In focal ischemia model with a complete occlusion of the middle cerebral artery in vivo, infarct at 24 h was significantly larger in Ca(v)2.3 mutant mice compared with that in wild-type controls. In vitro Ca2+ imaging studies using hippocampal slices revealed that oxygen-glucose deprivation induced a [Ca2+]i increase in the hippocampal CA1 region more vigorously in Ca(v)2.3 mutant mice than in wild-type controls, and that tetrodotoxin or bicuculline application abolished the difference between the genotypes. These results suggest that the Ca(v)2.3 channel plays a protective role in ischemic neuronal injury by a mechanism in which GABAergic neuronal actions are involved.

Topics: Animals; Bicuculline; Brain Ischemia; Calcium; Calcium Channels; Calcium Channels, R-Type; Cation Transport Proteins; Cerebral Infarction; GABA Antagonists; Genotype; Hippocampus; In Vitro Techniques; Mice; Mice, Mutant Strains; Nervous System; Sodium Channel Blockers; Tetrodotoxin

We investigated the pathophysiological mechanisms of glutamate-induced delayed neuronal damage in rat hippocampal slice cultures [Stoppini et al. (1991) J. Neurosci. Methods 37, 173-182], with propidium iodide as a marker of cell death. Exposure of the cultures to growth medium containing 10 mM glutamate for 30 min resulted in a slowly developing degeneration of hippocampal principal cells, starting from the medial end of the CA1 region and reaching the dentate gyrus by 48 h. By 24 h, most pyramidal cells in CA1 were damaged. An acute phase of degeneration preceded the delayed damage at 2-6 h, affecting cells in a spatially diffuse manner. When tetrodotoxin (0.5 microM) was present during the glutamate insult, a marked protection (mean 57%, P<0.001) of the CA1 damage was observed. Rather strikingly, when tetrodotoxin was applied immediately following or even with a delay of 30 min after the insult, a similar amount of protection was achieved. In field recordings carried out after the insult, the glutamate-treated slices exhibited spontaneously occurring negative shifts with a duration of 1-10 s and an amplitude of up to 400 microV in the CA3 region, whereas the control slices were always quiescent. Taken together, the results suggest that post-insult neuronal network activity, rather than the direct action of exogenous glutamate, is a major cause of delayed CA1 pyramidal cell death in the organotypic slices. These observations may have implications in the design of neuroprotective strategies for the treatment of brain traumas which are accompanied by delayed and/or distal neuronal damage.

Topics: Action Potentials; Animals; Brain Injuries; Brain Ischemia; Cell Death; Epilepsy; Glutamic Acid; Hippocampus; Nerve Degeneration; Nerve Net; Neurotoxins; Organ Culture Techniques; Pyramidal Cells; Rats; Tetrodotoxin; Time Factors

The mechanisms underlying the depression of evoked fast excitatory postsynaptic currents (EPSCs) following superfusion with medium deprived of oxygen and glucose (in vitro ischemia) for a 4-min period in hippocampal CA1 neurons were investigated in rat brain slices. The amplitude of evoked fast EPSCs decreased by 85 +/- 7% of the control 4 min after the onset of in vitro ischemia. In contrast, the exogenous glutamate-induced inward currents were augmented, while the spontaneous miniature EPSCs obtained in the presence of tetrodotoxin (TTX, 1 microM) did not change in amplitude during in vitro ischemia. In a normoxic medium, a pair of fast EPSCs was elicited by paired-pulse stimulation (40-ms interval), and the amplitude of the second fast EPSC increased to 156 +/- 24% of the first EPSC amplitude. The ratio of paired-pulse facilitation (PPF ratio) increased during in vitro ischemia. Pretreatment of the slices with adenosine 1 (A1) receptor antagonist, 8-cyclopenthyltheophiline (8-CPT) antagonized the depression of the fast EPSCs, in a concentration-dependent manner: in the presence of 8-CPT (1-10 microM), the amplitude of the fast EPSCs decreased by only 20% of the control during in vitro ischemia. In addition, 8-CPT antagonized the enhancement of the PPF ratio during in vitro ischemia. A pair of presynaptic volleys and excitatory postsynaptic field potentials (fEPSPs) were extracellularly recorded in a proximal part of the stratum radiatum in the CA1 region. The PPF ratio for the fEPSPs also increased during in vitro ischemia. On the other hand, the amplitudes of the first and second presynaptic volley, which were abolished by TTX (0.5 microM), did not change during in vitro ischemia. The maximal slope of the Ca(2+)-dependent action potential of the CA3 neurons, which were evoked in the presence of 8-CPT (1 microM), nifedipine (20 microM), TTX (0.5 microM), and tetraethyl ammonium chloride (20 mM), decreased by 12 +/- 6% of the control 4 min after the onset of in vitro ischemia. These results suggest that in vitro ischemia depresses the evoked fast EPSCs mainly via the presynaptic A1 receptors, and the remaining 8-CPT-resistant depression of the fast EPSCs is probably due to a direct inhibition of the Ca(2+) influx to the axon terminals.

Topics: Animals; Brain Ischemia; Calcium; Excitatory Postsynaptic Potentials; Hippocampus; In Vitro Techniques; Male; Neurons; Presynaptic Terminals; Purinergic P1 Receptor Antagonists; Rats; Rats, Wistar; Receptors, Purinergic P1; Tetrodotoxin; Theophylline

A prominent feature of cerebral ischemia is the excessive intracellular accumulation of both Na(+) and Ca(2+), which results in subsequent cell death. A large number of studies have focused on pathways involved in the increase of the intracellular Ca(2+) concentration [Ca(2+)](i), whereas the elevation of intracellular Na(+) has received less attention. In the present study we investigated the effects of inhibitors of different Na(+) channels and of the Na(+)/Ca(2+) exchanger, which couples the Na(+) to the Ca(2+) gradient, on ischemic damage in organotypic hippocampal slice cultures. The synaptically evoked population spike in the CA1 region was taken as a functional measure of neuronal integrity. Neuronal cell death was assessed by propidium iodide staining. The Na(+) channel blocker tetrodotoxin, and the NMDA receptor blocker MK 801, but not the AMPA/kainate receptor blocker NBQX prevented ischemic cell death. The novel Na(+)/Ca(2+) exchange inhibitor 2-[2-[4-(4-nitrobenzyloxy)phenyl]ethyl]isothiourea methanesulfonate (KB-R7943), which preferentially acts on the reverse mode of the exchanger, leading to Ca(2+) accumulation, also reduced neuronal damage. At higher concentrations, KB-R7943 also inhibits Ca(2+) extrusion by the forward mode of the exchanger and exaggerates neuronal cell death. Neuroprotection by KB-R7943 may be due to reducing the [Ca(2+)](i) increase caused by the exchanger.

Topics: Animals; Brain Ischemia; Cell Death; Culture Techniques; Dizocilpine Maleate; Electrophysiology; Hippocampus; Homeostasis; Hypoglycemia; Hypoxia; Neurons; Quinoxalines; Rats; Rats, Wistar; Receptors, AMPA; Receptors, Kainic Acid; Receptors, N-Methyl-D-Aspartate; Sodium; Sodium Channel Blockers; Sodium Channels; Sodium-Calcium Exchanger; Tetrodotoxin; Thiourea

Using middle cerebral artery occlusion (MCAO) and in vivo microdialysis, we have evaluated the changes in extracellular concentrations of the excitatory amino acids (EAA) glutamate and aspartate during varying periods of MCAO (0, 30, 60 min) in the striatum of spontaneously hypertensive rats (SHR). A positive correlation between occlusion time-dependent elevations in EAAs and the resulting ischemic injury was observed. This is the first demonstration of the temporal profile of EAA efflux during transient focal ischemia in SHRs. Possible sources and mechanisms of ischemia-induced EAA efflux were examined during 60 min of MCAO. Removal of Ca(2+) from the microdialysis infusion media significantly attenuated ischemia-induced increases in both glutamate (from ischemic peak of 4892 +/- 1298 to 1144 +/- 666% of preischemic values) and aspartate (from 2703 +/- 682 to 2090 +/- 599% of preischemic values). Similarly, infusion of the voltage dependent Na(+) channel blocker tetrodotoxin (TTX; 10 microM) significantly attenuated MCAO-induced increases in glutamate (to 1313 +/- 648%) and aspartate (to 359 +/- 114%). Infusion of the GLT-1 selective nontransportable inhibitor, dihydrokainate (DHK; 1 mM) also significantly attenuated the ischemia-induced increases in both EAAs (1285 +/- 508 and 1366 +/- 741% of the preischemic levels, respectively). These results indicate that during transient focal ischemia the increase in extracellular EAAs originates from both the neuronal pool, via conventional exocytotic release, and glial sources via the reversal of the GLT-1 transporter.

Topics: Amino Acid Transport System X-AG; Animals; Aspartic Acid; ATP-Binding Cassette Transporters; Brain; Brain Ischemia; Extracellular Space; Glutamic Acid; Infarction, Middle Cerebral Artery; Kainic Acid; Male; Rats; Rats, Inbred SHR; Reperfusion Injury; Tetrodotoxin; Time Factors

Striatal spiny neurons are selectively vulnerable to ischemia, but the ionic mechanisms underlying this selective vulnerability are unclear. Although a possible involvement of sodium and calcium ions has been postulated in the ischemia-induced damage of rat striatal neurons, the ischemia-induced ionic changes have never been analyzed in this neuronal subtype.. We studied the effects of in vitro ischemia (oxygen and glucose deprivation) at the cellular level using intracellular recordings and microfluorometric measurements in a slice preparation. We also used various channel blockers and pharmacological compounds to characterize the ischemia-induced ionic conductances.. Spiny neurons responded to ischemia with a membrane depolarization/inward current that reversed at approximately -40 mV. This event was coupled with an increased membrane conductance. The simultaneous analysis of membrane potential changes and of variations in [Na+]i and [Ca2+]i levels showed that the ischemia-induced membrane depolarization was associated with an increase of [Na+]i and [Ca2+]i. The ischemia-induced membrane depolarization was not affected by tetrodotoxin or by glutamate receptor antagonists. Neither intracellular BAPTA, a Ca2+ chelator, nor incubation of the slices in low-Ca2+-containing solutions affected the ischemia-induced depolarization, whereas it was reduced by lowering the external Na+ concentration. High doses of blockers of ATP-dependent K+ channels increased the membrane depolarization observed in spiny neurons during ischemia.. Our findings show that, although the ischemia-induced membrane depolarization is coupled with a rise of [Na+]i and [Ca2+]i, only the Na+ influx plays a prominent role in this early electrophysiological event, whereas the increase of [Ca2+]i might be relevant for the delayed neuronal death. We also suggest that the activation of ATP-dependent K+ channels might counteract the ischemia-induced membrane depolarization.

Topics: Adenosine Triphosphate; Animals; Brain Ischemia; Calcium; Calcium Channel Blockers; Calcium Channels; Cerebral Cortex; Chelating Agents; Corpus Striatum; Egtazic Acid; Glucose; Glyburide; Hypoglycemic Agents; Magnesium; Membrane Potentials; Neurons; Organ Culture Techniques; Oxygen; Patch-Clamp Techniques; Potassium Channel Blockers; Potassium Channels; Rats; Rats, Wistar; Receptors, Glutamate; Sodium; Sodium Channel Blockers; Sodium Channels; Tetrodotoxin; Tolbutamide

Experimental evidence supports a major role of increased intracellular calcium [Ca2+]i levels in the induction of neuronal damage during cerebral ischemia. However, the source of Ca2+ rise has not been fully elucidated. To clarify further the role and the origin of Ca2+ in cerebral ischemia, we have studied the effects of various pharmacological agents in an in vitro model of oxygen (O2)/glucose deprivation.. Pyramidal cortical neurons were intracellularly recorded from a slice preparation. Electrophysiological recordings and microfluorometric measurements of [Ca2+]i were performed simultaneously in slices perfused with a glucose-free physiological medium equilibrated with a 95% N2/5% CO2 gas mixture.. Eight to twelve minutes of O2/glucose deprivation induced an initial membrane hyperpolarization, followed by a delayed, large but reversible membrane depolarization. The depolarization phase was accompanied by a transient increase in [Ca2+]i levels. When O2/glucose deprivation exceeded 13 to 15 minutes, both membrane depolarization and [Ca2+]i rise became irreversible. The dihydropyridines nifedipine and nimodipine significantly reduced either the membrane depolarization or the [Ca2+]i elevation. In contrast, tetrodotoxin had no effect on either of these parameters. Likewise, antagonists of ionotropic and group I and II metabotropic glutamate receptors failed to reduce the depolarization of the cell membrane and the [Ca2+]i accumulation. Finally, dantrolene, blocker of intracellular Ca2+ release, did not reduce both electrical and [Ca2+]i changes caused by O2/glucose depletion.. This work supports a role of L-type Ca2+ channels both in the electrical and ionic changes occurring during the early phases of O2/glucose deprivation.

Topics: Animals; Brain Ischemia; Calcium; Calcium Channel Blockers; Calcium Channels; Cell Membrane; Cytophotometry; Dantrolene; Energy Metabolism; Excitatory Amino Acid Antagonists; Fluorescent Dyes; Fura-2; Glucose; Male; Membrane Potentials; Nifedipine; Nimodipine; Oxygen Consumption; Pyramidal Cells; Rats; Rats, Wistar; Tetrodotoxin; Time Factors

Peroxynitrite (ONOO-) is a powerful oxidant which is formed from the reaction between nitric oxide (NO) and superoxide anion. It has therefore been proposed to mediate the toxic actions caused by NO. Since ONOO- may be formed in the central nervous system (CNS) in pathological conditions such as brain ischaemia, we decided to investigate whether this molecule induces the release of the endogenous excitatory amino acids glutamate and aspartate from neurones. We selected as biological model acutely dissociated rat cerebellar granule neurones in suspension to allow a direct interaction between ONOO- and target cells. Peroxynitrite caused a concentration-dependent release of aspartate but not of glutamate from dissociated cerebellar granule neurones. Peroxynitrite-induced aspartate release was inhibited by dithiothreitol, tetrodotoxin, and in Na+-deprived solutions and not affected by EGTA or pre-incubation with the cytosolic Ca2+ chelator BAPTA/AM. Peroxynitrite also induced an increase in intracellular Ca2+ concentration which was not affected in the presence of EGTA. These data show that ONOO- causes release of aspartate from cerebellar granule neurones and that this effect might arise from an alteration of Na+ membrane permeability leading subsequently to reversal of a Na+-dependent plasma membrane transporter of this excitatory amino acid. In addition, ONOO- alters Ca2+ homeostasis likely due to Na+ overload. Taken together, these findings may help and elucidate some of the intimate mechanisms of NO-induced neuronal damage in pathological circumstances.

Topics: Animals; Aspartic Acid; Brain Ischemia; Calcium; Cerebellar Cortex; Dithiothreitol; Egtazic Acid; Glutamic Acid; Ion Transport; Kainic Acid; Membrane Proteins; Nerve Tissue Proteins; Neurons; Nitrates; Nitric Oxide; Oxidants; Oxidation-Reduction; Rats; Rats, Wistar; Sodium; Sulfhydryl Compounds; Superoxides; Tetrodotoxin

Immediate and delayed effects of glucose deprivation, oxygen deprivation (hypoxia) and both oxygen and glucose deprivation (in vitro ischemia) on glutamate efflux from guinea pig cerebral cortex slices were studied. Immediate effects were evaluated by measuring changes of glutamate efflux during the metabolic insults. Delayed effects were evaluated by measuring the response of the tissue to a 50 mM KCI pulse applied 60 min after the metabolic insults. Deprivation of glucose in the medium did not induce either immediate or delayed effects, while hypoxic condition produced an immediate slight stimulation of glutamate efflux without any delayed effect. Conversely, in vitro ischemia produced both immediate and delayed effects on glutamate efflux. During in vitro ischemia glutamate efflux dramatically increased in a calcium-independent and tetrodotoxin-sensitive manner; this effect was potentiated by a low sodium containing medium. The blockade of the sodium/potassium ATPase exchanger by ouabain caused a glutamate outflow similar to that induced by in vitro ischemia. On the whole, these data demonstrate the central role played by the sodium electrochemical gradient and by the membrane glutamate uptake system in the glutamate overflow induced by in vitro ischemia. Moreover, in slices previously exposed to both oxygen and glucose deprivation the effect of KCI on glutamate efflux was potentiated. This in vitro ischemia-induced delayed potentiation of neurotransmitter efflux, until now unreported in the literature, was found to be selectively restricted to glutamatergic structures and to be mainly due to an enhancement of the exocytotic component of glutamate release.

Topics: Animals; Brain Ischemia; Calcium; Cerebral Cortex; Female; Glutamic Acid; Guinea Pigs; Hypoxia; In Vitro Techniques; Male; Ouabain; Potassium Chloride; Sodium; Tetrodotoxin; Time Factors

In the present study we have examined the effects of the small organic molecules: NNC 09-0026 ((-)-trans-1-butyl-4-(4-dimethylaminophenyl)-3-[(4-trifluoromethyl-ph eno xy) methyl] piperidine dihydrochloride); SB 201823-A (4-[2-(3,4-dichlorophenoxy)ethyl]-1-pentyl piperidine hydrochloride); NS 649 (2-amino-1-(2,5-dimethoxyphenyl)-5-trifluoromethyl benzimidazole); CNS 1237 (N-acenaphthyl-N'-4-methoxynaphth-1-yl guanidine) and riluzole on human omega-conotoxin sensitive N-type voltage-dependent Ca2+ channel currents (ICa) expressed in HEK293 cells, on Na+ channel currents (INa) in acutely isolated cerebellar Purkinje neurones in vitro and in the gerbil model of global cerebral ischaemia in vivo. Estimated IC50 values for steady-state inhibition of ICa were as follows; NNC 09-0026, 1.1 microM; CNS 1237, 4.2 microM; SB 201823-A, 11.2 microM; NS 649, 45.7 microM and riluzole, 233 microM. Estimated IC50 values for steady-state inhibition of Na+ channel currents were as follows: NNC 09-0026, 9.8 microM; CNS 1237, 2.5 microM; SB 201823-A, 4.6 microM; NS 649, 36.7 microM and riluzole, 9.4 microM. In the gerbil model of global cerebral ischaemia the number of viable cells (mean +/- S.E.M.) per 1 mm of the CA1 was 215 +/- 7 (sham operated), 10 +/- 2 (ischaemic control), 44 +/- 15 (NNC 09-0026 30 mg/kg i.p.), 49 +/- 19 (CNS 1237 30 mg/kg i.p.), 11 +/- 2 (SB 201823-A 10 mg/kg i.p.), 17 +/- 4 (NS 649 50 mg/kg i.p.) and 48 +/- 18 (riluzole 10 mg/kg i.p.). Thus NNC 09-0026, CNS 1237 and riluzole provided significant neuroprotection when administered prior to occlusion while SB 201823-A and NS 649 failed to protect. These results indicate that the Ca2+ channel antagonists studied not only inhibited human N-type voltage-dependent Ca2+ channels but were also effective blockers of rat Na+ channels. Both NNC 09-0026 and CNS 1237 showed good activity at both Ca2+ and Na+ channels and this may contribute to the observed neuroprotection.

Topics: Animals; Brain Ischemia; Calcium Channel Blockers; Calcium Channels; Cell Line; Dizocilpine Maleate; Excitatory Amino Acid Antagonists; Gerbillinae; Guanidines; Humans; Male; Mollusk Venoms; Neuroprotective Agents; omega-Conotoxins; Peptides; Piperidines; Rats; Receptors, N-Methyl-D-Aspartate; Riluzole; Sodium Channel Blockers; Sodium Channels; Tetrodotoxin

Ischemic neuronal injury is supposed to be caused in part by the extracellular accumulation of excitatory amino acids (EAA). Neurotransmitter and metabolic EAA can be released from synaptic vesicles and cytoplasm of neurones and glial cells. In this study the release of the glutamate analogue [3H]D-aspartate ([3H]D-ASP), loaded into 500 microns slices of rat hippocampus, was investigated. The efflux of the label was measured during anoxic-aglycemic ("ischemic") and normoxic K+ depolarization. To identify the pools from which [3H]D-ASP is released we have estimated its calcium dependence and the effects of inhibitors of: (1) Na(+)-dependent transporter of amino acids (100 microM L-trans-pyrrolidine-2,4-dicarboxylic acid/L-trans-PDC/), (2) sodium channel (1 microM tetrodotoxin TTX), and (3) anion channel (1 mM furosemide). [3H]D-ASP released upon normoxic depolarization was 40% inhibited by TTX, nearly 40% by L-trans-PDC and over 50% by furosemide. The "ischemic" release was in 40% calcium dependent, completely TTX independent and in approximately 50% blocked by furosemide treatment. Our data suggest that EAA accumulated in the synaptic cleft during ischemia are mainly released from the cytosolic compartment by mechanisms which are connected with the ischemic increase of extracellular potassium concentration.

Topics: Animals; Aspartic Acid; Brain Ischemia; Chelating Agents; Egtazic Acid; Hippocampus; In Vitro Techniques; Rats; Tetrodotoxin

Because recent reports point to Na+ channel blockers as protective agents directed against anoxia-induced neuronal damage including protection of anaerobic glycolysis, the influences of tetrodotoxin (TTX) and (+/-)-kavain on anoxic rat brain vesicles were investigated with respect to lactate synthesis, vesicular ATP content and cytosolic free Na+ and Ca2+ ([Na+]i, [Ca2+]i), both of the latter determined fluorometrically employing SBFI and FURA-2, respectively. After anoxia, basal lactate production was increased from 2.9 to 9.8 nmol lactate/min/mg protein. Although lactate synthesis seemed to be stable for at least 45 min of anoxia, as deduced from the linearity of lactate production, the ATP content declined continuously with a half life (tau 1/2) of 14.5 min, indicating that anaerobic glycolysis was insufficient to cover the energy demand of anoxic vesicles. Correspondingly, [Na+]i and [Ca2+]i increased persistently after anoxia by 22.1 mmol/l Na+ and 274.9 nmol/l Ca2+, determined 6.3 min after onset. An additional stimulation of vesicles with veratridine accelerated the drop of ATP (tau 1/2 = 5.1 min) and provoked a massive Na+ overload, which levelled off to 119 mmol/l Na+ within a few minutes. Concomitantly, [Ca2+]i increased linearly with a rate of 355 nmol Ca2+/l/min. Despite the massive perturbation of ion homeostasis, lactate production was unaffected during the first 8 min of veratridine stimulation. However, complete inhibition of lactate synthesis took place 30 min after veratridine was added. The Na+ channel blockers TTX and (+/-)-kavain, if applied before anoxia, preserved vesicular ATP content, diminished anoxia-induced increases in [Na+]i and [Ca2+]i and prevented both the veratridine-induced increases of [Na+]i and [Ca2+]i and the inhibition of lactate production. The data indicate a considerable Na+ influx via voltage-dependent Na+ channels during anoxia, which speeds up the decline in ATP and provokes an increase in [Ca2+]i. A massive Na+ and Ca2+ overload induced by veratridine failed to influence lactate synthesis directly, but initiated its inhibition.

Topics: Adenosine Triphosphate; Anaerobiosis; Animals; Anticonvulsants; Benzofurans; Brain; Brain Ischemia; Calcium; Ethers, Cyclic; Fluorescent Dyes; Fura-2; Glycolysis; Hypoxia, Brain; Kinetics; Lactates; Male; NAD; Oxygen Consumption; Pyrones; Rats; Rats, Wistar; Sodium; Sodium Channel Blockers; Tetrodotoxin

We evaluated concentrations of excitatory amino acids released from slices into the superfusing solution and also evaluated extracellular field potential recordings and histological appearance of slice tissues to evaluate several sodium-channel modulating drugs as potential treatments for ischemia. The selective sodium-channel blocker tetrodotoxin (TTX, 1 microM) reduced glutamate release from deprivation of oxygen and D-glucose, while calcium-channel blockade was ineffective. Thus, during ischemia, we propose that glutamate may be released from the free cytosolic pool ('metabolic' glutamate) rather than by exocytosis. TTX (100-500 nM) and voltage-dependent sodium-channel blockers (phenytoin, 20-100 microM; lidocaine, 2-200 microM) each prevented damage to slices without blocking action potentials. The reduction of cellular depolarization and sodium loading during ischemia may explain the neuroprotective action of several sodium-channel modulating drugs in our in vitro studies and also in animal models.

Topics: Animals; Brain Ischemia; Electrophysiology; Glutamic Acid; Hippocampus; In Vitro Techniques; Phenytoin; Rats; Rats, Inbred Strains; Sodium Channel Blockers; Tetrodotoxin; Time Factors

Clinical and experimental evidence has shown that the striatal neurons are particularly vulnerable to hypoxia and ischaemia. An excessive excitatory action of glutamate, released by the corticostriatal terminals, has been implicated in this peculiar vulnerability of striatal neurons. We have studied the effects of hypoxia on the membrane properties of striatal neurons intracellularly recorded from a corticostriatal slice preparation. Brief (2-10 min) periods of hypoxia produced reversible membrane depolarizations. During the initial phase of the hypoxia-induced depolarization the frequency of action potential discharge was transiently increased; 2-3 min after the onset of hypoxia the firing activity was fully abolished. Brief periods of hypoxia also caused a reversible reduction of the amplitude of the excitatory postsynaptic potentials (EPSPs) evoked by cortical stimulation. Longer period of hypoxia (12-20 min) produced irreversible membrane depolarizations. In voltage-clamp experiments hypoxia caused an inward current coupled with an increased membrane conductance. Tetrodotoxin (TTX) or low calcium (Ca2+)-high magnesium containing solutions blocked synaptic transmission, but they did not reduce the hypoxia-induced electrical changes. Antagonists of excitatory amino acid receptors failed to affect the electrical effects caused by oxygen deprivation. Hypoxia-induced inward currents were reduced either by the potassium (K+) channel blockers, barium and tetraethyl ammonium (TEA) cations, or by lowering external sodium (Na+) concentration. Blockade of ATP-dependent Na(+)-K+ pump by both ouabain and strophanthidin enhanced hypoxia-induced membrane depolarization/inward current. Our findings indicate that the release of excitatory amino acids does not seem to be required for the acute hypoxia-induced electrical changes in striatal neurons. Moreover, TTX-resistant Na+ influx and K+ currents seem to play an important role in the generation of hypoxia-induced electrical changes. These data also suggest that the selective vulnerability of striatal neurons to oxygen deprivation may be caused by their peculiar sensitivity to energy metabolism failure.

Topics: Animals; Brain Ischemia; Calcium; Corpus Striatum; Electric Conductivity; Excitatory Amino Acids; Glutamic Acid; Hypoxia, Brain; Male; Membrane Potentials; Rats; Rats, Wistar; Sodium-Potassium-Exchanging ATPase; Tetraethylammonium; Tetraethylammonium Compounds; Tetrodotoxin

1. Ischaemia was induced by 5 min of deprivation of glucose and an additional 5 min of deprivation of glucose and oxygen from Mg(2+)-free artificial cerebrospinal fluid in vitro. 2. During the ischaemic period, 11 +/- 1.5% of the total [3H]-dopamine ([3H]-DA) was released into the incubation medium. 3. Ischaemia-evoked release of [3H]-DA from striatal slices was attenuated by tetrodotoxin (TTX), MgSO4, dizocilpine, ketamine, 6,7-dinitroquinoxaline-2,3-dione (DNQX) or carbetapentane. 4. Release of [3H]-DA was attenuated by verapamil, omega-conotoxin GVIA and dantrolene. 5. Nomifensin inhibited the ischaemia-induced release of [3H]-DA. 6. Omission of Ca(2+) from incubation media potentiated ischaemia-evoked [3H]-DA release. The inhibitory effect of nomifensin was potentiated in Ca(2+)-free incubation media. 7. These results suggest that ischaemia induces release of [3H]-DA by dual mechanisms; one is Ca(2+)-dependent exocytosis and the other is reversal of transporter.

Topics: Animals; Brain Ischemia; Calcium; Calcium Channel Blockers; Corpus Striatum; Culture Techniques; Cyclopentanes; Dantrolene; Dizocilpine Maleate; Dopamine; Ketamine; Magnesium Sulfate; Nomifensine; omega-Conotoxin GVIA; Peptides; Quinoxalines; Rats; Tetrodotoxin; Verapamil

Neuronal damage induced by ischemia involves various changes in neurotransmission. Nitric oxide (NO), a putative neurotransmitter and/or neuromodulator has some role in this neuronal damage. In the present study, the effect of NO on the terminal site of dopamine (DA) neurons in the rat striatum was examined using the microdialysis technique. First perfusion with sodium nitroprusside (SNP) as an NO donor increased extracellular DA (10 mM, 460%; 1 mM, 140%) in the striatum and decreased its metabolites. Pretreatment with tetrodotoxin (TTX, 5 microM), (+)-5-methyl-10,11-dihydro-5H-dibenzo [a,d] cyclohepten-5,10-imine hydrogen maleato (MK801, 1 microM) or muscimol (1 microM) inhibited SNP-induced increases in extracellular DA and decreases in DOPAC (TTX, complete block; MK801, 75% inhibition; muscimol, 80% inhibition). Second, extracellular NO, DA and DOPAC were measured in the gerbil striatum following 10 minutes of forebrain ischemia produced by occluding both carotid arteries. Occlusion of the carotid arteries also caused increases in extracellular NO and DA in the gerbil striatum (NO, 3000%; DA, 2800%). These findings suggest that NO-facilitated DA release occurs via interaction between glutamatergic and dopaminergic neurons. These changes are probably partially involved in the neurodegenerative phenomena following ischemia. It is also shown that simultaneous measurements of NO and DA using this technique may be useful in assessing ischemic changes in vivo.

Topics: 3,4-Dihydroxyphenylacetic Acid; Animals; Brain Ischemia; Chromatography, High Pressure Liquid; Corpus Striatum; Dizocilpine Maleate; Dopamine; Gerbillinae; Male; Microdialysis; Nitric Oxide; Nitroprusside; Rats; Rats, Wistar; Tetrodotoxin

In vitro ischemia (IVI) was simulated with rat hippocampal slices in medium lacking D-glucose, equilibrated with 95% nitrogen, 5% carbon dioxide. Within 5-8 min, synaptic potentials disappeared and a DC negative shift (5-15 mV) occurred. Prolonged application of 95% oxygen and D-glucose 12 min later did not allow synaptic potentials to recover. Slices pretreated with sodium channel blocking drugs allowed synaptic potentials to recover after IVI. Tetrodotoxin (TTX, 100-600 nM), the anticonvulsant phenytoin (5.0 to 100 microM) and the local anesthetic lidocaine (2.0 to 200 microM) each delayed or prevented negative DC shifts from IVI. Histological examination showed that drug treatments also prevented CA1 pyramidal cell damage from IVI. Neuroprotection occurred without blocking synaptic potentials or presynaptic fiber volleys, suggesting relevance for treatment of brain ischemia.

Topics: Action Potentials; Animals; Brain Ischemia; Evoked Potentials; Hippocampus; Hypoxia, Brain; In Vitro Techniques; Lidocaine; Male; Phenytoin; Rats; Rats, Wistar; Synaptic Transmission; Tetrodotoxin

The purpose of this study was to evaluate potential mechanisms of ischemia-evoked amino acid transmitter release. Changes in extracellular levels of transmitter amino acids and lactic acid dehydrogenase (LDH) in rat cerebral cortex during and following four-vessel occlusion elicited global cerebral ischemia were examined using a cortical cup technique. Ischemia-evoked release of glutamate, aspartate and gamma-amino-butyric acid (GABA) was compared in control vs. drug-treated animals. Tetrodotoxin and antagonists of glutamate receptors (DNQX, MK-801, and AP-3) depressed the initial rate of increase in extracellular glutamate and aspartate without altering the total amount of these amino acids collected in the cortical superfusates. Cobalt, a calcium channel antagonist, failed to alter efflux. Acidic amino acid transport inhibitors (dihydrokainate, L-trans-PDC) depressed the rate of onset of glutamate and aspartate release and dihydrokainate depressed total release by 44%. PD 81723, an allosteric enhancer at the A1 adenosine receptor, depressed glutamate efflux, as did L-NAME, an inhibitor of nitric oxide synthase. Extracellular increases in GABA levels were depressed by tetrodotoxin and L-trans-PDC. The GABA transport inhibitor, nipecotic acid, increased the initial rate of onset of GABA release. Increases in LDH levels in the extracellular fluid became apparent during the period of ischemia and continued to increase during the subsequent 90 min of reperfusion. These results suggest that ischemia evokes a release of neurotransmitter amino acids that is only partially dependent upon Ca2+ influx activation or the reversal of amino acid transporters. Nonselective mechanisms, resulting from the disruption of plasma membrane integrity, may contribute significantly to the total ischemia-evoked release of excitatory amino acids.

Topics: Amino Acid Transport System X-AG; Animals; Aspartic Acid; Biological Transport; Brain Ischemia; Cerebral Cortex; Excitatory Amino Acid Antagonists; GABA Antagonists; gamma-Aminobutyric Acid; Glutamates; Glutamic Acid; Glycoproteins; L-Lactate Dehydrogenase; Male; Rats; Rats, Sprague-Dawley; Tetrodotoxin

Anoxic depolarization (AD) and failure of the cellular ion homeostasis are suggested to play a key role in ischemia-induced neuronal death. Recent studies show that the blockade of Na+ influx significantly improved the neuronal outcome. In the present study, we investigated the effects of 10 microM tetrodotoxin (TTX) on ischemia-induced disturbances of ion homeostasis in the isolated perfused rat brain. TTX inhibited the spontaneous EEG activity, delayed the ischemia-induced tissue acidification, and significantly postponed the occurrence of AD by 65%. The [Ca2+]e elevation prior to AD was attenuated from 17.8% to 6% while the increase of the [Na+]e in this period was enhanced (from 2.9% to 7.3%). These findings implied that the ischemia-induced early cellular sodium load and the corresponding shrinkage of the extracellular space was counteracted by TTX. Our results suggest that the Na+ influx via voltage-dependent channels preceding complete breakdown of ion homeostasis is one major factor leading to cell depolarization. The massive Na+ influx coinciding with AD, however, may be mainly via non-selective cation channels or/and receptor-operated channels. Persistent Na+ influx deteriorates neuronal tissue integrity by favouring Ca2+ influx and edema formation. Blockade of ischemia-induced excessive Na+ influx is, therefore, a promising pharmacological approach for stroke treatment.

Topics: Animals; Brain Chemistry; Brain Ischemia; Cell Membrane Permeability; Cerebral Cortex; Electroencephalography; Electrophysiology; Homeostasis; Male; Microelectrodes; Oxygen Consumption; Perfusion; Rats; Sodium Channels; Tetrodotoxin

Studies examining the role of tetrodotoxin-sensitive ion channels in hypoxic-ischemic neuronal damage have concluded that sodium influx is an important initiating event. We examined the neuroprotectant effect of tetrodotoxin on both cultured cerebellar neurons and on CA1 hippocampal neurons of gerbils exposed to brain ischemia.. We studied neuroprotective mechanisms using cultured rat cerebellar granule cells exposed to veratridine, which induced cytotoxicity, neurotransmitter release, and calcium influx. Survival of gerbil CA1 neurons was examined by direct neuron counts 7 days after 6 minutes of global ischemia with reperfusion.. Tetrodotoxin protected cultured neurons in a dose-dependent manner from veratridine-induced toxicity (protective concentration [PC50] = 22 nmol/L). Veratridine induced [3H]aspartate efflux that was sodium dependent, only 25% calcium dependent, and was inhibited by tetrodotoxin (inhibitory concentration [IC50] = 60 nmol/L). Veratridine initiated increases in intracellular calcium that were also reversed by tetrodotoxin (IC50 = 63 nmol/L); reversal was dependent on the sodium-calcium exchanger and the sodium-potassium pump. Neuroprotection of 90% (n = 10; P = .001 versus vehicle) of gerbil CA1 hippocampal neurons was achieved by pretreatment with 2 ng of tetrodotoxin delivered three times intracerebroventricularly, without causing hypothermia.. Sodium channel blockers like tetrodotoxin may have utility in treatment of ischemic neuronal injury by preventing excessive neuronal depolarizations, limiting excitotoxic glutamate release through reversal of the sodium-dependent glutamate transporter, preventing intracellular calcium overload, preserving cellular energy stores, and allowing recovery of ionic homeostasis through operation of the sodium-calcium exchanger.

Topics: Animals; Aspartic Acid; Brain; Brain Ischemia; Calcium; Calcium-Transporting ATPases; Cells, Cultured; Cerebellum; Dose-Response Relationship, Drug; Excitatory Amino Acid Antagonists; Gerbillinae; Glutamic Acid; Hippocampus; Ion Transport; Neurons; Neurotransmitter Agents; Rats; Rats, Sprague-Dawley; Reperfusion; Sodium Channel Blockers; Sodium Channels; Sodium-Potassium-Exchanging ATPase; Tetrodotoxin; Veratridine

The hippocampus demonstrates a regional pattern of vulnerability to ischemic injury that depends on its characteristic differentiation and intrinsic connections. We now describe a model of ischemic injury using organotypic hippocampal culture, which preserves the anatomic differentiation of the hippocampus in long-term tissue culture.. Ischemic conditions were modeled by metabolic inhibition. Cultures were briefly exposed to potassium cyanide to block oxidative phosphorylation and 2-deoxyglucose to block glycolysis. The fluorescent dye propidium iodide was used to observe membrane damage in living cultures during recovery.. 2-Deoxyglucose/potassium cyanide incubation resulted in dose-dependent, regionally selective neuronal injury in CA1 and the dentate hilus, which began slowly after 2 to 6 hours of recovery. Subsequent histological examination of cultures after 1 to 7 days of recovery demonstrated neuronal pyknosis that was correlated with the early, direct observation of membrane damage with propidium. Both propidium staining and histological degeneration were prevented by the noncompetitive N-methyl-D-aspartate (NMDA) receptor antagonist MK-801 when administered 30 minutes after the end of the exposure to 2-deoxyglucose and potassium cyanide. Tetrodotoxin, which blocks voltage-dependent sodium channels, had protective effects that were greatest during the period of 2-deoxyglucose and potassium cyanide incubation but also produced protection against the mildest conditions of metabolic inhibition when administered after 30 minutes of recovery.. This in vitro model reproduced elements of the time course, regional vulnerability, and pharmacologic sensitivities of in vivo ischemic hippocampal injury. Inhibition of metabolism in organotypic culture provides a rapid, easily controlled injury and reproduces the in vitro pattern of hippocampal regional vulnerability to ischemia. It is the first in vitro model of ischemia to exhibit complete protection by delayed administration of an NMDA receptor antagonist during recovery from a brief insult. The protective effects of tetrodotoxin suggest that an early period of sodium entry into cells during and after ATP depletion may be responsible for the more prolonged period of toxic NMDA receptor activation.

Topics: Animals; Brain Ischemia; Deoxyglucose; Disease Models, Animal; Dizocilpine Maleate; Glycolysis; Hippocampus; Neurons; Organ Culture Techniques; Oxidative Phosphorylation; Potassium Cyanide; Pyramidal Tracts; Rats; Tetrodotoxin; Time Factors

The effects of the potassium channel openers lemakalim, RP 52891 and galanin and the potassium channel blockers glibenclamide and gliquidone were evaluated by the release of endogenous glutamate from rat hippocampal slices subjected to a brief period of ischaemia (2-10 min). Ischaemia was mimicked by incubating slices in a glucose free medium equilibrated with 95% N2/5% CO2. These conditions evoked a release of glutamate which was insensitive to tetrodotoxin and Ca2+ indicating a non-vesicular origin. The release of glutamate evoked by a 6- or 8-min period of ischaemia was reduced by 25-40% in the presence of lemakalim (10 microM), RP 52891 (10 microM) or galanin (0.3 microM), whereas it was enhanced by 60 to 100% in the presence of glibenclamide (1 microM) and gliquidone (2 microM). These observations suggest that cellular damage resulting from ischaemia induced excessive release of glutamate in the hippocampus may be partly reduced by potassium channel openers, and conversely increased by sulfonylureas.

Topics: Animals; Brain Ischemia; Glucose; Glutamates; Glutamic Acid; Hippocampus; In Vitro Techniques; Male; Oxygen Consumption; Potassium Channels; Rats; Rats, Wistar; Tetrodotoxin

The characteristics of adenosine and inosine outflow evoked by 5 min of ischemia-like conditions in vitro (superfusion with glucose-free Krebs solution gassed with 95% N2/5% CO2) were investigated on rat hippocampal slices. The viability of the slices after "ischemia" was evaluated by extracellular recording of the evoked synaptic responses in the CA1 region. The evoked dendritic field potentials were abolished after 5 min of superfusion under "ischemia" but a complete recovery occurred after 5 min of reperfusion with normal oxygenated Krebs solution. No recovery took place after 10 min of "ischemia." The addition of the adenosine A1 receptor antagonist 8-phenyltheophylline to the superfusate antagonized the depression of the evoked field potentials caused by 5 min of "ischemia." Five minutes of "ischemia" brought about a six- and fivefold increase in adenosine and inosine outflow, respectively, within 10 min. Tetrodotoxin reduced the outflow of adenosine and inosine by 42 and 33%, respectively, whereas the removal of Ca2+ caused a further increase. The NMDA receptor antagonist D(-)-2-amino-7-phosphonoheptanoic acid and the non-NMDA antagonist 6,7-dinitroquinoxaline-2,3-dione brought about small, not statistically significant decreases of adenosine and inosine outflow. The glutamate uptake inhibitor dihydrokainate did not affect the outflow of adenosine and inosine. Inhibition of ecto-5'-nucleotidase by alpha,beta-methylene ADP and GMP did not affect basal adenosine outflow but potentiated "ischemia"-evoked adenosine outflow. It is concluded that ischemia-like conditions in vitro evoke a Ca(2+)-independent adenosine and inosine outflow, through a mechanism that partly depends on propagated nervous activity but does not involve excitatory amino acids.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: 5'-Nucleotidase; Adenosine; Amino Acids; Animals; Brain Ischemia; Calcium; Electric Stimulation; Electrophysiology; Hippocampus; In Vitro Techniques; Inosine; Male; Rats; Rats, Wistar; Tetrodotoxin

[3H]dopamine ([3H]DA) release was measured from rat striatal slices under normoxic and hypoxic conditions. In some experiments hypoxia was combined with glucose withdrawal. Hypoxia increased the evoked release of dopamine without affecting resting release. Hypoglycemia itself increased only the resting release of [3H]DA. In the absence of glucose hypoxia provoked a dramatic rise in both resting and stimulation-evoked release of dopamine. This effect was partly reduced by Ca2+ withdrawal, and was abolished in the presence of tetrodotoxin (1 microM). The NMDA-receptor antagonist MK-801 (3 microM) attenuated the effect of hypoxia and hypoglycemia on [3H]DA release. It was suggested that activation of NMDA receptors is involved in dopamine release during hypoxia and energy deprivation.

Topics: Animals; Brain Ischemia; Cell Hypoxia; Corpus Striatum; Disease Models, Animal; Dizocilpine Maleate; Dopamine; Glucose; Male; Rats; Rats, Wistar; Receptors, N-Methyl-D-Aspartate; Tetrodotoxin

To determine the role of tetrodotoxin-sensitive ion channels in post-ischemic selective neuronal death, the effect of tetrodotoxin on ischemia-induced brain cell injury was studied in rats. The animals were subjected to 20 min of cerebral ischemia in a four vessels occlusion model. Thirty min before ischemia, tetrodotoxin at a dose of 10(-7) or 10(-6) M was topically applied into the hippocampal CA1 subfield. Morphological changes in the CA1 subfield were evaluated 7 days after ischemia and compared with those of a vehicle-injected group. The average cell density of CA1 pyramidal neurons ipsilateral to the injection (cells/mm, mean +/- S.E.M.) was 27 +/- 7 (n = 6) in the vehicle-treated group, and 56 +/- 13 (n = 6) and 83 +/- 17 (n = 6) in the group treated with tetrodotoxin at doses of 10(-7) and 10(-6) M, respectively. Tetrodotoxin mitigated the ischemic hippocampal neuronal damage in a limited but dose-dependent manner. This suggests that activation of tetrodotoxin-sensitive ion channels might contribute to the process of the ischemic neuronal damage.

Topics: Animals; Brain Ischemia; Hippocampus; Ion Channels; Male; Nervous System Diseases; Pyramidal Tracts; Rats; Rats, Inbred Strains; Tetrodotoxin

An excessive activation of the excitatory amino acid system has been proposed as one possible mediator of the ischemia-induced delayed death of CA1 pyramidal cells in the hippocampus. Using dialytrodes in the CA1 of the rat, we have investigated multiple-unit activity and extracellular changes in acidic sulfur-containing amino acids and gamma-glutamyl peptides during ischemia (20-min, four-vessel occlusion) and during 8 h of reflow. Multiple-unit activity was abolished during ischemia and for the following 1 h, but then recovered, gradually reaching preischemic levels after 8 h of reflow. Extracellular cysteate, cysteine sulfinate, and gamma-glutamyltaurine increased (1.5- to threefold) during ischemia, and extracellular glutathione and gamma-glutamylaspartate plus gamma-glutamylglutamine increased during early reflow (two- to threefold). The recovery of neuronal activity at 4-8 h was paralleled by an increase in extracellular cysteine sulfinate (2.5-fold at 8 h of reflow). Perfusion with 10 microM tetrodotoxin at 8 h of reflow abolished the multiple-unit activity and reduced extracellular cysteine sulfinate. Considering the glutamate-like properties of cysteine sulfinate, the observed postischemic increase may be involved in the development of the delayed neuronal death.

Topics: Acids; Amino Acids; Animals; Brain Ischemia; Cysteine; Dipeptides; Electrochemistry; Extracellular Space; Glutamine; Hippocampus; Male; Neurons; Neurotransmitter Agents; Rats; Rats, Inbred Strains; Sulfur; Taurine; Tetrodotoxin

Calcium accumulation and neuronal injury were studied after hypoxia in cerebrocortical cell cultures in vitro. Neuronal injury was associated with a delayed calcium accumulation, which was greatest 5-7 hours after hypoxic exposure. Antiexcitotoxic treatments with tetrodotoxin and magnesium chloride or the selective N-methyl-D-aspartate antagonist (+/-)-4-(3-phosphonopropyl)-2-piperazinecarboxylic acid prevented hypoxic calcium accumulation and neuronal injury even when added 3 hours after hypoxia, during reoxygenation. Rescue of the neurons after hypoxia by blocking the delayed calcium accumulation in this cell culture preparation suggests a "therapeutic window" determined by calcium entry.

Topics: Animals; Brain Ischemia; Calcium; Cerebral Cortex; Culture Techniques; Hypoxia, Brain; Neurons; Piperazines; Rats; Receptors, N-Methyl-D-Aspartate; Tetrodotoxin

Early changes in tissue extracellular space following exposure to the excitotoxin kainate in the striatum were compared to those following cardiac arrest of rats anesthetized by chloral hydrate. Tissue extracellular space was monitored by impedance measurements. The possible role of voltage-sensitive Na channels and energy metabolism was studied by local and systemic application of tetrodotoxine (TTX) and glucose, respectively. After both kainate intoxication and cardiac arrest the extracellular space (normally about 20%) became less than one-half within 15 min. TTX caused a delay in the effect of cardiac arrest, and a slight attenuation of that of kainate. Glucose was ineffective in both preparations. Parallel to a decrease in the extracellular space whole tissue Na/K ratio increased. These experiments show that excitotoxins and cardiac arrest cause similar (and not additive) changes in the extracellular space and that these changes are not mediated by Na channels. In cardiac arrest the onset of the extracellular space alterations is triggered by Na+ influx, thus presumably by neurotransmitter release. It is suggested that most (if not all) currently described protective measures against ischemic, hypoxic, or hypoglycemic brain damage are based on a prolongation of the time of onset leading to cell depolarization, rather than suppressing damaging processes during depolarization.

Topics: Animals; Brain Ischemia; Corpus Striatum; Electric Stimulation; Extracellular Space; Female; Kainic Acid; Male; Membrane Potentials; Rats; Rats, Inbred Strains; Tetrodotoxin

The effects of in vitro anoxia and membrane depolarization by veratridine on the uptake and release of amino acids were investigated in suspensions of synaptosomes isolated from the forebrains of rats. It was observed that GABA, aspartate and glutamate were released from synaptosomes in anaerobic conditions and upon addition of veratridine in a time-dependent manner. The release of the two latter amino acids was faster and more pronounced than that of GABA. The other amino acids were not affected in any systematic way by either condition. Re-introduction of oxygen or addition of tetrodotoxin to veratridine-treated synaptosomes resulted in the re-uptake of GABA, aspartate and glutamate, which was much faster and more complete for GABA than for the acidic amino acids, especially at acid pH values. The amounts of aspartate and glutamate in the incubation mixture remained constant during all the manipulations whereas that of GABA increased by about 30% during anaerobiosis, in agreement with the results obtained during in vivo ischemia. It is postulated that synaptosomes which utilize glutamate and aspartate as neurotransmitters are more damaged by anoxia and depolarization with veratridine than the population which utilizes GABA. These observations may explain reports that those neurons which are thought to receive major glutamatergic input are particularly sensitive to the lack of oxygen.

Topics: Amino Acids; Animals; Aspartic Acid; Brain; Brain Ischemia; Culture Techniques; gamma-Aminobutyric Acid; Glutamates; Glutamic Acid; Hydrogen-Ion Concentration; Hypoxia, Brain; Male; Neurotransmitter Agents; Rats; Rats, Inbred Strains; Synaptosomes; Tetrodotoxin; Veratridine

The effect of anoxia and ischemia on the release of amino acid transmitters from cerebellar slices induced by veratridine or high [K+] was studied. Synaptic specificity was tested by examining the tetradotoxin (TTX)-sensitive and the Ca2+-dependent components of stimulated release. Evoked release of endogenous amino acids was investigated in addition to more detailed studies on the stimulated efflux of preloaded [14C]GABA and D-[3H]aspartate (a metabolically more stable anologue of acidic amino acids). [14C]GABA release evoked by either method of stimulation was unaffected by periods of up to 35 min of anoxia and declined moderately by 45 min. In contrast, induced release of D-[3H]Asp increased markedly during anoxia to a peak at about 25 min, followed by a decline when anoxia was prolonged to 45 min. Evidence was obtained that the increased evoked efflux of D'[3H]Asp from anoxic slices was not due to impaired reuptake of the released amino acid and that it was completely reversible by reoxygenation of the slices. Results of experiments examining the evoked release of endogenous amino acids in anoxia were consistent with those obtained with the exogenous amino acids. Only 4 of the 10 endogenous amino acids studied exhibited TTX-sensitive veratridine-induced release under aerobic conditions (glutamate, aspartate, GABA, and glycine). Anoxia for 25 min did not affect the stimulated efflux of these amino acids with the exception of glutamate, which showed a significant increase. Compared with anoxia, effects of ischemia on synaptic function appeared to be more severe. Veratridine-evoked release of [14C]GABA was already depressed by 10 min and that of D-[3H[Asp showed a modest elevation only a 5 min. Stimulated release of D-Asp and labelled GABA declined progressively after 5 min. These findings were compared with changes in tissue ATP concentrations and histology. The latter studies indicated that in anoxia the earliest alterations are detectable in glia and that nerve terminals were the structures by far the most resistant to anoxic damage. The results thus indicated that evoked release of amino acid transmitters in the cerebellum is compromised only by prolonged anoxia in vitro. In addition, it would appear that the stimulated release of glutamate is selectively accentuated during anoxia. This effect may have a bearing on some hypoxic behavioral changes and, perhaps, also on the well-known selective vulnerability of certain neurons during hypoxia.

Topics: Amino Acids; Animals; Aspartic Acid; Brain Ischemia; Cerebellum; Female; gamma-Aminobutyric Acid; Glutamates; Glutamic Acid; Glycine; Hypoxia; In Vitro Techniques; Kinetics; Male; Neurotransmitter Agents; Potassium; Rats; Rats, Inbred Strains; Tetrodotoxin