Anoxia increases potassium conductance in hippocampal nerve cells

Plasma membrane hyperpolarization by cyanide in chromaffin cells: role of potassium channels

Exposure of rat pheochromocytoma (PC12) cells to cyanide produces elevation of cytosolic calcium, impaired Na(+)-H+ exchange, membrane lipid peroxidation and release of neurotransmitters. Since these observations suggested cyanide alters plasma membrane function, the present study examined the effect of NaCN on the membrane potential of undifferentiated PC12 cells in suspension. In PC12 cells loaded with the voltage sensitive fluorescent dye, bis-oxonol, cyanide (2.5-10 mM) elicited an immediate (within seconds), concentration related decrease in fluorescence, indicating hyperpolarization of the plasma membrane. Increasing extracellular K+ concentration to 20 mM blocked the effect of cyanide (5 mM), suggesting cyanide increased K+ efflux. Pretreatment with quinine blocked the cyanide-induced hyperpolarization, whereas glyburide had little effect, showing the hyperpolarization produced by cyanide was due to activation of Ca2+ sensitive K+ channels. Removal of Ca2+ from the media did not influence cyanide-induced hyperpolarization. However, buffering intracellular Ca2+ by loading cells with the Ca2+ chelators, Quin II or BAPTA, abolished the cyanide effect, showing cytosolic Ca2+ is a key factor. These findings suggest that cyanide mobilizes Ca2+ from intracellular stores which leads to hyperpolarization via the activation of Ca2+ sensitive K+ channels.

Responses of CA1 pyramidal neurons in rat hippocampus to transient forebrain ischemia: an in vivo intracellular recording study

The electrophysiological responses of CA1 pyramidal neurons to 5 min forebrain ischemia were studied with intracellular recording and staining techniques in vivo. The baseline membrane potential rapidly depolarized to approximately -20 mV about 3 min after the onset of ischemia and began to repolarize 1-3 min after recirculation. The amplitude of this ischemic depolarization (ID) was related directly to the severity of ischemia and its latency of onset was inversely related to brain temperature. Spontaneous synaptic activity ceased shortly after ischemia onset while the evoke synaptic potentials lasted until shortly before the onset of ID. Inhibitory postsynaptic potentials (IPSPs) disappeared earlier than excitatory postsynaptic potentials (EPSPs) and the membrane input resistance of CA1 neurons increased after the onset of ischemia.

Vulnerability of CA1 neurons in SHRSP hippocampal slices to ischemia, and its protection by Ca2+ channel blockers

Vulnerability of CA1 pyramidal neurons to hypoxic and hypoglycemic insult was compared in hippocampal slices between the stroke-prone spontaneously hypertensive rat (SHRSP) and its mother strain, Wistar Kyoto rat (WKY). Stimulation of Schaffer collateral-commissural fibers induced D-2-amino-5-phosphonovalerate sensitive multi-component population spikes in slices from both strains when the external K+ concentration was elevated. The K+ concentration required for this phenomenon was significantly lower in SHRSP slice preparations than in those from WKY. The hypoxic and hypoglycemic insult in slice preparations is assumed to be equivalent to ischemic conditions in vivo. Although the short-term 'ischemic' insult caused a complete loss of population spikes in slices from both strains, a transient hyperexcitability, spreading depression-like depolarization, accumulation of extracellular K+ and reduction of extracellular Ca2+ occurred in SHRSP slices, but not in WKY. Time required for partial recovery of the population spike following the 'ischemic' insult was markedly increased in SHRSP slices compared with WKY. Thus, CA1 pyramidal neurons of SHRSP were more vulnerable to 'ischemic' insult than those of WKY. This vulnerability of pyramidal neurons in the SHRSP strain was independent of its hypertensive phenotype. A novel L-type Ca2+ channel blocker, S-312-d, its stereoisomer, S-312-1, and nimodipine protected the 'ischemic' insult-induced neuronal dysfunction at submicromolar concentrations. It is concluded that hippocampal neurons in SHRSP are innately vulnerable. This vulnerability is suggested to be due, at least in part, to some abnormality in K+ channel channels of hippocampal neurons.

Modulation of locus coeruleus neurons by extra- and intracellular adenosine 5'-triphosphate

The cell membrane of rat locus coeruleus (LC) neurons is sensitive to both extra- and intracellular ATP. Extracellular ATP or its enzymatically stable analogues activate membrane receptors of the P2 type. These receptors inhibit a persistent potassium current and simultaneously activate a nonselective cationic conductance. The resulting depolarization increases the spontaneous firing rate. A decrease in the concentration of intracellular ATP during hypoxia or hypoglycemia opens ATP-sensitive K+ (KATP) channels of LC neurons. The resulting hyperpolarization depresses the discharge of action potentials and conserved energy. The hypoxia-induced hyperpolarization is additionally due to the release of adenosine from neighboring neurons or glial cells. A certain class of compounds, termed potassium channel openers, also decrease the firing, while sulphonylurea antidiabetics known to block KATP channels increase it. Sulphonylurea antidiabetics antagonize the excitability decrease induced both by potassium channel openers and metabolic damage.

Channel shutdown: a response of hippocampal neurons to adverse environments

Stretch-activated ion channels have been discovered in the membrane of many types of cells, but their presence in neurons is uncertain. We used freshly dissociated rat hippocampal neurons to study the effect of hypotonic swelling but, surprisingly, the isolated neurons did not swell. Voltage-dependent whole-cell membrane currents mediated by K+, Na+ and Ca2+ were rapidly and reversibly suppressed during sudden exposure to strongly hypo-osmotic, hyper-osmotic or glucose deficient solutions. The amplitudes of the sustained components of K+ and Ca2+ currents were more depressed than transient currents, but the rate of decay of transient K+ current greatly accelerated. The voltage dependence of activation and of steady state inactivation of residual K+ and Ca2+ currents were not shifted. The current holding membrane potential at -70 mV and therefore the conductance at that voltage were unchanged or somewhat decreased. Capacitive (charging) membrane current was not affected. Changes in tail current suggested moderate loss of cytosolic K+ in some but not in all cells. We conclude that channel shutdown is a uniform response of neuron somata and proximal dendrites to various adverse environments. Hypothetically we propose that swelling was prevented in anisosmotic conditions because membrane water permeability decreased.

Membrane currents in CA1 pyramidal cells during spreading depression (SD) and SD-like hypoxic depolarization

We used the patch clamp technique in whole-cell configuration to investigate the membrane current and membrane resistance of neurons in rat hippocampal tissue slices during spreading depression (SD) induced by high K+ solution or electrical stimulation and during SD-like depolarization caused by hypoxia. The potential of the patch pipette was referred to an extracellular micropipette electrode to ensure control of the true membrane potential during large shifts of extracellular potential, delta Vo. During both hypoxic and normoxic SD, increase of holding current indicated a large inward current which reached a mean maximum of about 1.75 nA. This virtual inward current started and ended at the same time as the extracellularly recorded negative delta Vo shift, but the trajectories of the two differed. When the membrane was clamped at strongly positive potential, the current during SD was outward. The average apparent reversal potential of the current during SD was near zero but in individual cases varied from -26 mV to + 12 mV. During SD the input resistance decreased on the average to 43% of the resting control value. The decrease of the input resistance was not voltage dependent. The increase of holding current and decrease of resistance occurred with both Cs- and K-gluconate recording pipettes and was not suppressed by 2 mM intracellular QX-314. Voltage-gated currents disappeared during SD; a small, Cs(+)-resistant outward rectifying current was the last to be lost. During recovery, reversal potential and input resistant overshot the control level and then returned to normal within about 5 min. The data are consistent with change of both driving potential and conductance for several ions, but the decrease of overall membrane resistance was less than earlier estimates with other methods had suggested. Normoxic SD and hypoxic SD-like depolarization could not be distinguished by these tests.

Tolbutamide suppresses anoxic outward current of hippocampal neurons

In hippocampal slices, 2-3 min of hypoxia often evokes a hyperpolarisation or outward current. In the presence of tetrodotoxin and kynurenic acid (to minimize indirect effects of the drugs), we applied two sulphonylureas to detect a possible involvement of ATP-sensitive K (KATP) channels. In all 9 cells tested, tolbutamide (TOLB, 0.1-1 mM) greatly reduced both the hypoxic current (by 81.3 +/- 9.4%) and the conductance increase (by 77.2 +/- 10.2%). By contrast, glibenclamide (GLIB, 10-30 microM) tested on 5 cells, had no comparable effects. We therefore conclude that if KATP channels play a role in the hypoxic response, they are likely to be of the low affinity type found in neocortical and hypothalamic neurons.

Evolving concepts about the role of acidosis in ischemic neuropathology

Cerebral ischemia is one of the most common neurological insults. Many pathological events are undoubtedly triggered by ischemia, but only recently has it become accepted that ischemic cell injury arises from a complex interaction between multiple biochemical cascades. Tissue acidosis is a well established feature of ischemic brain tissue, but its role in ischemic neuropathology is still not fully understood. Within the last few years, new evidence has challenged the historically negative view of acidosis and suggests that it may play more of a beneficial role than previously thought. This review reintroduces the concept of acidosis to ischemic brain injury and presents some new perspectives on its neuroprotective potential.

Neuronal damage in the rat hippocampus induced by in vivo hypoxia

Rats were subjected to hypoxia for 30 min in a chamber containing 5% O2 and 95% N2. The distribution of damaged neurons in the hippocampus was then examined at various predetermined times, ranging from 3 hours to 21 days after hypoxia. Hematoxylin-eosin stained sections showed shrunken and eosinophilic neurons in the CA3 and CA4 regions. Similar, but less severe, changes were also observed in the granule cell layer of the dentate gyrus. In contrast, neurons in the CA1 region were relatively resistant to hypoxia. These results showed the susceptibility of the hippocampus to hypoxia, although the affected neurons are not the same as those vulnerable to ischemia.

Dissociation of cyclic GMP level from relaxation of the distal, but not the proximal colon of rats

The role of cyclic GMP (cGMP) in nonadrenergic, noncholinergic (NANC) relaxation of the longitudinal muscle of rat proximal and distal colon was examined. Electrical field stimulation (EFS) of preparations of longitudinal muscle from the proximal region significantly increased the cGMP content. Nitro-L-arginine inhibited this increase, and L-arginine reversed the inhibitory effect of nitro-L-arginine. Exogenously added nitric oxide (NO) and atrial natriuretic peptide (ANP) also increased the cGMP content of preparations of the proximal colon and induced muscle relaxation. From these and our previous findings suggesting an essential role of NO in NANC inhibition in the proximal colon, we conclude that the mechanism of NANC inhibition in the proximal region of rat colon involves NO and a cGMP generating system. In contrast, although exogenously added NO and ANP increased the cGMP content in the distal colon to the same extent as in the proximal colon, they did not induce any muscle relaxation. Vasoactive intestinal peptide (VIP), the most likely candidate as a NANC neurotransmitter in rat distal colon, did not increase the cGMP content in this region. Furthermore, no participation of NO in the NANC inhibitory response was observed in the distal region, but EFS increased the cGMP content significantly. Thus we conclude that relaxation of longitudinal smooth muscle in the distal portion of rat colon is not associated with a change in the cGMP content.

The NMDA receptor contributes to anoxic aglycemic induced irreversible inhibition of synaptic transmission

Percent recovery of CA1 field EPSP amplitude following various anoxic aglycemic (AA) periods was examined in rat hippocampal slices superfused with MK-801 (0.1 microM, 1 microM, 10 microM) or Mg(2+)-free artificial cerebrospinal fluid. Slices treated with 0.1 microM MK-801 showed greater percent recuperation of EPSP amplitude following 3 min 30 s of AA (36 +/- 12% vs 6 +/- 4% in controls). Higher concentrations of MK-801 resulted in a greater recovery of EPSP amplitudes in more than one time period of AA, with 10 microM MK-801 providing protection in up to 4 min 30 s AA. Percent recuperation of EPSP amplitude was smaller in Mg(2+)-free slices following 2 min (34 +/- 15% vs 81 +/- 11% in controls) and 2 min 30 (25 +/- 14% vs 77 +/- 10% in controls) of AA. These results suggest that the activation of the N-methyl-D-aspartate (NMDA) receptor channel may contribute to irreversible AA induced synaptic failure in CA1.

Coupling of cellular energy state and ion homeostasis during recovery following brain ischemia

The present experiments were undertaken to explore the relationship between recovery of cerebral energy state following transient ischemia, and resumption of Na+/K+ transport, as this is reflected in changes in extracellular K+ concentration ([K+]c). Cerebral energy state was evaluated by measurements of cerebral cortical concentrations of phosphocreatine (PCr), ATP, ADP, and AMP at the end of 15 min of severe, incomplete ischemia, as well as after 2 and 5 min of recirculation. Derivation of intracellular pH (pHi) allowed calculation of 'free' ADP (ADPf) and AMP (AMPf) concentrations. Changes in [K+]e were measured by an ion-sensitive microelectrode. The results showed that tissue ATP concentration, which was close to zero after 15 min of ischemia, rose to 30% of control after 2 min, and to 60% of control after 5 min of recirculation. However, since the adenine nucleotide pool was reduced by the ischemia the latter value represents extensive or complete phosphorylation of that pool, as reflected in a normalized ATP/ADPf ratio. During recirculation, the concentration of pyruvate rose, but the lactate content remained unchanged, suggesting that the substrate for oxidative metabolism was exogenous glucose. Resumption of Na+/K+ transport, as reflected in the [K+]e began after 2-3 min, and a normal [K+]e was attained within 5 min. The results demonstrate that transport of Na+ and K+ is resumed at tissue ATP concentrations which are only 30-40% of control. It is discussed whether this reflects relatively extensive rephosphorylation of the remaining adenine nucleotide pool, or if compartmentation of adenine nucleotides exists during recirculation.

Human neocortical excitability is decreased during anoxia via sodium channel modulation

When the central nervous system in humans is deprived of oxygen, the effects are potentially disastrous. Electroencephalographic activity is lost and higher brain function ceases rapidly. Despite the importance of these effects, the mechanisms underlying the loss of cortical activity are poorly understood. Using intracellular recordings of human neocortical neurons in tissue slices, we show that, whereas anoxia produces a relatively small depolarization and modest alterations in passive properties, it causes a major decrease in excitability. Whole-cell voltage-clamp studies of acutely isolated human neocortical pyramidal neurons demonstrate that anoxia and metabolic inhibition produce a large negative shift in the steady-state inactivation [h infinity (V)] curve for the voltage-dependent sodium current (INa). Inclusion of ATP in the patch pipette decreased the shift of the h infinity (V) curve by two-thirds. Because increased inactivation of INa decreases cellular metabolic demand, we postulate that this promotes neuronal survival during periods of oxygen deprivation. These data show a novel mechanism by which anoxia links metabolism to membrane ionic conductances in human cortical neurons.

Influence of hypoxia on excitation and GABAergic inhibition in mature and developing rat neocortex

To analyze the functional consequences of hypoxia on the efficacy of intracortical inhibitory mechanisms mediated by gamma-aminobutyric acid (GABA), extra- and intracellular recordings were obtained from rat primary somatosensory cortex in vitro. Hypoxia, induced by transient N2 aeration, caused a decrease in stimulus-evoked inhibitory postsynaptic potentials (IPSPs), followed by a pronounced anoxic depolarization. Upon reoxygenation, the fast (f-) and long-latency (l-) IPSP showed a positive shift in the reversal potential by 24.4 and 14.9 mV, respectively. The peak conductance of the f- and l-IPSP was reversibly reduced in the postanoxic period by 72% and 94%, respectively. Extracellular field potential recordings and application of a paired-pulse inhibition protocol confirmed the enhanced sensitivity of inhibitory synaptic transmission for transient oxygen deprivation. Intracellular recordings from morphologically or electrophysiologically identified interneurons did not reveal any enhanced susceptibility for hypoxia as compared to pyramidal cells, suggesting that inhibitory neurons are not selectively impaired in their functional properties. Intracellularly recorded spontaneous IPSPs were transiently augmented in the postanoxic period, indicating that presynaptic GABA release was not suppressed. Developmental studies in adult (older than postnatal day 28), juvenile (P14-18), and young (P5-8) neocortical slices revealed a prominent functional resistance of immature tissue for hypoxia. In comparison with adult cortex, the hypoxia-induced reduction in excitatory and inhibitory synaptic transmission was significantly smaller in immature cortex. Our data indicate a hypoxia-induced distinct reduction of postsynaptic GABAergic mechanisms, leading to the manifestation of intracortical hyperexcitability as a possible functional consequence.

Ionic basis of membrane potential changes induced by anoxia in rat dorsal vagal motoneurones

1. The effects of anoxia on membrane properties of 119 dorsal vagal motoneurones (DVMs) were investigated in an in vitro slice preparation of the rat medulla. 2. Membrane potential was unaffected by anoxia in 11% of DVMs. An hyperpolarization accompanied by a decrease in input resistance occurred in 44% of DVMs; the remaining 45% depolarized with either an increase (60%) or decrease in input resistance (40%). TTX at a concentration of 0.3-1 microM did not significantly affect these responses. 3. Anoxic artificial cerebrospinal fluid (ACSF) containing 20 mM-TEA reversed the response of DVMs that hyperpolarized in standard ACSF to reveal a depolarization of 7.4 +/- 2.1 mV, and increased the anoxic depolarization from 5.0 +/- 0.7 to 8.7 +/- 1.4 mV. 4. Anoxic depolarization was converted to an hyperpolarization of 7.3 +/- 2.1 mV in ACSF containing 5 mM-4-aminopyridine (4-AP) and 1 microM-TTX. A residual depolarization of 4.5 +/- 3.5 mV was then observed in ACSF containing 5 mM-4-AP, 1 microM-TTX and 20 mM-TEA. Anoxic hyperpolarization was increased from 7.8 +/- 1.8 to 10.0 +/- 3.9 mV in 5 mM-4-AP and 1 microM-TTX and converted to a depolarization of 5.3 +/- 4.5 mV in 5 mM-4-AP, 1 microM-TTX and 20 mM-TEA. 5. In anoxic ACSF containing TEA, the action potential width was increased from 0.92 +/- 0.04 to 8.1 +/- 1.1 ms in hyperpolarizing DVMs, and from 0.85 +/- 0.01 to 2.4 +/- 1.0 ms in depolarizing DVMs. The increase in width was prevented by 2-3 mM-Mn2+. 6. The long after-hyperpolarization (AHP) of DVMs, which is contributed to by both an apamin-sensitive IK(Ca) and an apamin, charybdotoxin and TEA insensitive IK(Ca) was decreased in duration from 2.59 +/- 0.14 to 1.94 +/- 0.12 s during anoxia. 7. It is concluded that anoxia enhances the delayed rectifier current (IK(DR)) and an inward current, probably ICa, but suppresses the A currents (IA). In DVMs that hyperpolarize during anoxia, the increase in IK(DR) outweighs the increase in ICa and the decrease in IA. In depolarizing DVMs the decrease in IA and increase in ICa outweight the increase in IK(DR). The change in input resistance is determined by the relative sizes of current enhancement or suppression.

Inhibition of energy metabolism by 3-nitropropionic acid activates ATP-sensitive potassium channels

3-Nitropropionic acid (1 mM), which inhibits succinate dehydrogenase activity and reduces cellular energy, produces in the pyramidal cell layer of the hippocampal region CA1 a hyperpolarization for variable lengths of time before evoking an irreversible depolarization. Hyperpolarization is caused by an increased potassium conductance that is attenuated by glibenclamide (1-10 microM), a selective antagonist of ATP-sensitive potassium channels; in contrast, diazoxide (0.5 mM), an agonist at this channel, induces a hyperpolarization in CA1 neurons of rat hippocampal slices. The transient hyperpolarization after prolonged (ca. 1 h) application of 3-NPA is followed by a depolarization that is incompletely reversed by brief application of the glutamate antagonists (D-2-amino-5-phosphonopentanoic acid (APV), 6,7-dichloroquinoxaline-2,3-dione (CNQX), 3-(+/-)-2-carboxypiperazin-4-yl)propyl-1-phosphonic acid (CPP), 7-chloro-kynurenic acid (7Cl-KYN)). Early application of glibenclamide (within the initial 5 min) blocked or reduced hyperpolarization and accelerated the depolarization. These data suggest that metabolic inhibition by 3-NPA initially activates ATP-sensitive potassium channels. Events other than activation of glutamate receptors participate in the final depolarization resulting from uncoupling of oxidative phosphorylation.

Protective effects of felbamate against hypoxia in the rat hippocampal slice

BACKGROUND AND PURPOSE

Felbamate is a new dicarbamate anticonvulsant with low toxicity currently being investigated in human clinical epilepsy trials. In this study, we examined the protective effects of felbamate against hypoxia.

METHODS

We exposed paired rat hippocampal slices to hypoxia with and without felbamate treatment while monitoring the CA1-evoked population spike.

RESULTS

Felbamate provided dose-dependent neuroprotection against hypoxia at concentrations of 45 mg/l and greater (p less than 0.05). At a felbamate concentration of 300 mg/l, recovery of CA1 evoked population spike amplitude after hypoxic exposure was 99% compared with 0.5% for unmedicated paired slices. The appearance and disappearance of the hypoxic injury potential was delayed in slices treated with 300 and 400 mg/l (p less than 0.05).

CONCLUSIONS

In this model of hypoxia, felbamate provided neuroprotection against hypoxia at concentrations similar to serum felbamate levels currently being used in human clinical epilepsy trials.

Metabolic inhibition and electrical properties of type-1-like cortical astrocytes

Type-1-like cortical mouse astrocytes were studied in homogeneous cultures. Membrane input resistance and membrane potential were measured during drug-induced inhibition of glycolysis (sodium fluoride), mitochondrial respiration (antimycin-a) and Na+/K+ pump activity (ouabain). It was found that the electrical properties of the astrocytes recovered after a 60 min period with inhibited glycolysis or mitochondrial respiration, exhibiting only small reversible depolarizations. A 60 min period of high K(+)-induced depolarization, of cell swelling or of Na+/K+ pump inhibition does not lead to irreversible changes. Total block of energy metabolism, however, causes (1) a large depolarization, which is mainly mediated by external calcium, and (2) a 10-fold increase in input resistance, suggestive of an uncoupling of gap junctions. After an exposure period ranging between 45 and 60 min these conditions lead to irreversible damage. This damage appears to be independent of extracellular calcium and the degree of depolarization and to be specifically mediated by events occurring after the 60-min period of inhibited cell metabolism, that is during the recovery period.

Suppression of presynaptic calcium currents by hypoxia in hippocampal tissue slices

We tested the hypothesis that suppression of inward calcium current in presynaptic terminals is the cause of failure of synaptic transmission early during cerebral hypoxia. Postsynaptic responses in CA1 zone of hippocampal tissue slices were blocked either by the combined administration of 6,7-dinitroquinoxaline-2,3-dione (DNQX) and 3-((+-)-2-carboxypiperazine-4-yl)-propyl-1-phosphonic acid (CPP) or by lowering extracellular calcium concentration ([Ca2+]o). Repetitive orthodromic activation of central neurons caused transient decrease of [Ca2+]o (measured by ion selective microelectrodes) in neuropil, attributable to influx of Ca2+ in presynaptic terminals. Presynaptic [Ca2+]o responses were rapidly and reversibly suppressed when oxygen was withdrawn from hippocampal tissue slices. The 'resting' baseline level of [Ca2+]o declined at first gradually, then precipitously as in spreading depression (SD). Presynaptic volleys during high frequency train stimulation were also depressed somewhat before SD began. We conclude that (1) presynaptic Ca2+ currents fail during hypoxia, perhaps because 'resting' intracellular free Ca2+ activity is increased and, in part, also because of partial failure of presynaptic impulse conduction; (2) the influx of Ca2+ into brain cells in hypoxic spreading depression is not mediated by glutamate/aspartate dependent channels.

Perturbation of cellular energy state in complete ischemia: relationship to dissipative ion fluxes

Loss of cellular ion homeostasis during anoxia, with rapid downhill fluxes of K+, Ca2+, Na+ and Cl-, is preceded by a slow rise in extracellular K+ concentration (Ke+), probably reflecting early activation of a K+ conductance. It has been proposed that this conductance is activated by either a rise in intracellular calcium concentration (Cai2+), or by a fall in ATP concentration. In a previous study from this laboratory (Folbergrová et al. 1990) we explored whether the early activation of a K+ conductance could be triggered by a rise in Cai2+. To that end, labile metabolites and phosphorylase a, a calcium sensitive enzyme, were measured after 15, 30, 60 and 120 s of complete ischemia ("anoxia"). In the present study, we investigated whether brief anoxia is accompanied by changes in ATP/ADP ratio, or in the phosphate potential, which could cause activation of a K+ conductance. To provide information on this issue, we added a group with 45 s of anoxia to the previously reported groups, and derived changes in intracellular pH (pHi). This allowed calculations of the free concentrations of ADP (ADPf) and AMP (AMPf) from the creatine kinase and adenylate kinase equilibria, and hence the derivation of ATP/ADPf ratios. In performing these calculations we initially assumed that the free intracellular Mg2+ concentration remained unchanged at 1 mM. However we also explored how a change in Mgi2+ of the type described by Brooks and Bachelard (1989) influenced the calculation. The results showed that ADPf must have risen to 150-200% of control within 15 s, and to 330-350% of control within 45 s of anoxia.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of transient forebrain ischemia and reperfusion on function of dopaminergic neurons and dopamine reuptake in vivo in rat striatum

To clarify functional changes of dopaminergic neurons and dopamine (DA) reuptake during and after ischemia, extracellular DA levels in striatum were determined using in vivo brain microdialysis in a 4-vessel occlusion model of male Wistar rats with and without pharmacological interventions. Without interventions, the extracellular DA levels markedly increased during ischemia, but upon reperfusion, rapidly returned to control level. Infusion of tetrodotoxin, a blocker of voltage-dependent Na+ channels, was without effect on the DA surge during ischemia, but decreased the DA levels after reperfusion to the same extent as in control rats. Pretreatment with nomifensine, an inhibitor of DA reuptake, was also without effect on the surge, but reduced the rate of DA decline after reperfusion to one-fifth of the rate without the pretreatment. When nomifensine was administered 40 min after reperfusion, extracellular DA levels increased to the same extent as in control rats. Infusion of high K+ 1 h after reperfusion induced a smaller increase in extracellular DA levels than that in control rats. It took 96 h for this reduced response to high K+ stimulation to recover after reperfusion. These results suggest that the DA surge during ischemia is mainly derived from action potential-independent DA release (means dysfunction of dopaminergic neurons), although activity of DA reuptake is completely inhibited. After reperfusion, the basal function of dopaminergic neurons and activity of DA reuptake rapidly recover, but the neurons are functionally disturbed to release less DA in response to a given stimulus for several days.

Enhancement of NMDA receptor-mediated neurotoxicity in the hippocampal slice by depolarization and ischemia

Evidence from animal stroke models suggests that the proximate cause of neuronal degeneration after ischemia is massive release of glutamate and activation of NMDA receptors. However, in the physiologic presence of oxygen and glucose in the rat hippocampal slice preparation, the neurotoxicity of glutamate, as measured by inhibition of protein synthesis, requires high concentrations and is not prevented by glutamate receptor antagonists. Thus, the NMDA receptor-mediated neurotoxic effects of extracellular glutamate accumulation during ischemia might depend on additional factors, such as neuronal depolarization. In the experiments reported here, slices were exposed to glutamate in a medium intended to mimic the ionic conditions found during ischemia, high potassium (128 mM) and low sodium (26 mM). This depolarizing medium itself inhibited protein synthesis in a manner which was partially mediated by NMDA receptor activation, since it was significantly reversed by the noncompetitive NMDA antagonist, MK-801. Furthermore, the effect of glutamate under depolarizing conditions was also significantly decreased by MK-801, suggesting that glutamate was acting at NMDA receptors. Thus, depolarization appears to enhance the sensitivity of neurons to toxic NMDA receptor activation by glutamate. Under conditions that mimic ischemia, hypoxia plus hypoglycemia, a similar protective effect of NMDA receptor antagonists was observed. Depolarization and ischemia both appeared to attenuate the neurotoxicity of non-NMDA receptor agonists. It appears that under conditions of normal glucose and oxygen, high concentrations of bath applied glutamate inhibit protein synthesis at sites other than the NMDA receptor. However, when the Na+ gradient is decreased, as occurs during ischemia, glutamate's NMDA effects predominate. These findings suggest that ionic shifts may play a central role in permitting NMDA receptor-mediated ischemic neuronal damage.

Differential sensitivity to hypoxia of the peripheral versus central trajectory of primary afferent axons

Myelinated primary afferent fibers have both peripheral and central nervous system components. As the fibers course through peripheral nerve and dorsal roots they are myelinated by Schwann cells, but after they invade the spinal cord they become myelinated by oligodendrocytes and have associations with astrocytes. This presents the opportunity to compare the pathophysiology of PNS (Schwann cell-associated) vs. CNS (oligodendrocyte/astrocyte-associated) portions of the same axonal trunk located in the dorsal roots and dorsal columns, respectively. Dorsal spinal roots and slices of dorsal columns isolated from adult rats were studied in a sucrose gap chamber from which compound action potential and membrane potential changes could be recorded. The results indicate that the peripheral component of the afferent fibers is resistant to hypoxia as evidenced by stable action and membrane potential when O2 in the bathing medium was completely replaced with N2 for periods up to 2 h. In contrast, the axons become sensitive to hypoxia as they project through the dorsal columns as evidenced by rapid reduction in action potential amplitude accompanied by membrane depolarization when O2 is replaced by N2. This differential response to hypoxia, observed on the same axon branches but over CNS vs. PNS trajectories, suggests that differences related to the extracellular environment or in axo-glial organization in dorsal root vs. dorsal column may confer different degrees of susceptibility to anoxia.

Ischemic brain slice glucose utilization: effects of slice thickness, acidosis, and K+

Brain slices of varying thickness were used to modify retention of metabolic products in an in vitro model of ischemia. Past and present results reveal increased anaerobic glycolysis in 660-microns slices with accumulation of lactate as slice thickness reaches 1,000 microns. Brain slice glucose utilization and lactate content were measured in buffers of various extracellular K+ levels and pH in 540-, 660-, and 1,000-microns slices. Acidosis suppresses glucose utilization at all slice thicknesses without affecting tissue lactate. Studies of 2-deoxyglucose metabolites establish that the suppression of glucose utilization by acidosis is due entirely to inhibition of glucose phosphorylation without any effect on glucose uptake into tissue. The inhibition is reversible after 45 min at pH 6.1. The experiments with acidosis also suggest that persistent energy demands continue to stimulate phosphofructokinase despite the low pH so that glycolysis continues, with potential for injury. Increasing K+ increases glucose utilization and tissue lactate at all three thicknesses. Correlations of glucose utilization with lactate accumulation support the possibility that high K+ may exert a dual influence on the tissue metabolism, not only stimulating glucose utilization by inducing depolarization but also by influencing the removal of metabolic products.

Depolarizing effects of anoxia on pyramidal cells of rat neocortex

The response of rat neocortical pyramidal neurons (layers II III) in vitro to brief periods of anoxia is a reversible depolarization of 3.8 +/- 1.01 mV (mean +/- S.E.M.; n = 114), which is accompanied by a moderate decrease in input resistance and significant depression of evoked synaptic activity. This effect is mimicked by ouabain, and is partially attenuated by the excitatory amino acid (EAA) antagonist, kynurenic acid. The estimated reversal potential (Vrev) for the anoxic depolarization (AD) is between -35 and -40 mV; in the presence of TTX a Vrev of -65 mV is obtained. Although a partial failure of Na(+)-K(+) pump activity and release of EAAs may contribute the generation of the AD, other processes are likely to be involved.

Ion channel involvement in hypoxia-induced spreading depression in hippocampal slices

Rat hippocampal tissue slices were made hypoxic in control medium and in medium containing the ion channel blockers tetraethylammonium (TEA), 4-aminopyridine (4-AP), or tetrodotoxin (TTX). Postsynaptic evoked potentials, extracellular DC potential Vec, and in some experiments extracellular potassium concentration [K+]o were monitored in stratum pyramidale of the CA1 region. TEA (10 mM) decreased the latency of hypoxia-induced spreading depression (SD), and reduced the amplitudes of the changes in Vec and [K+]o. 4-AP (50 microM) also decreased the latency of SD but had no effect on the Vec shift. In most slices, TTX (1 microM) increased SD latency but had no effect on the Vec shift. In some slices, TTX blocked the occurrence of SD.

K+ efflux pathways and neurotransmitter release associated to hippocampal ischemia: effects of glucose and of K+ channel blockers

Ischemia of hippocampal slices leads to 86Rb+ efflux and to amino acid neurotransmitter release. This 86Rb+ efflux which corresponds to the massive K+ efflux from neuronal cells observed in ischemic animals is inhibited by glucose (IC50 = 1.7 mM). Glucose also inhibits the ischemia induced liberation of GABA and aspartate. 86Rb+ efflux is insensitive to any type of known blockers for ATP-sensitive, Ca2(+)-sensitive and voltage-sensitive K+ channels.

Extracellular ions during veratridine-induced neurotoxicity in hippocampal slices: neuroprotective effects of flunarizine and tetrodotoxin

Veratridine, by blocking Na+ channel inactivation and shifting activation to more negative membrane potentials, causes Na(+)-influx and a persistent tendency for depolarization. Veratridine is neurotoxic to cultured neurones, and this neurotoxicity can be blocked by the class IV calcium antagonist, flunarizine. We were interested to know whether similar effects could be found in a functional differentiated tissue containing adult neurones and glial cells. We examined this in hippocampal slices using extracellular potential recordings and ion-selective microelectrodes sensitive to [Na+]o, [Ca2+]o and [K+]o. Veratridine blocked synaptic transmission in CA1, and induced several episodes of spreading depression (SD). This was followed by a long-lasting increase in [K+]o and a continuous decrease in [Ca+]o. Following veratridine exposure to hypoxia only revealed a small negative DC shift and small shifts in extracellular ions; indicating that the cells had lost the ability to maintain ion homeostasis before the hypoxia, and that veratridine had been neurotoxic. In hippocampal slices obtained from guinea pigs which had been pretreated with 40 mg/kg x 2 flunarizine orally the time before the first SD induced by veratridine was doubled. Although the ion shifts during the first SD were similar to controls, flunarizine reduced the time of recovery of [Ca2+]o, [K+]o and DC potential. The increase in [K+]o baseline and the massive decrease in [Ca2+]o baseline seen following the SDs in the solvent group were smaller in the flunarizine-treated slices. During the subsequent hypoxic period the negative DC shift was 8x larger in the flunarizine group, and the shifts in [K+]o, [Na+]o and [Ca2+]o were bigger. Tetrodotoxin also delayed the first SD during veratridine and increased the size of the DC shift during the subsequent hypoxic period. Both flunarizine and tetrodotoxin therefore protected adult brain tissue containing glia from the neurotoxicity of veratridine. These findings suggest that persistent Na(+)-influx and the consequent Ca2(+)-influx produce neurotoxicity, and that the ability to attenuate this neurotoxicity may be important in the mechanism of action of cerebroprotective drugs from different pharmacological classes.

Hypoxic failure of synaptic transmission in the isolated spinal cord, and the effects of divalent cations

Responses evoked by stimulation of a dorsal root were recorded from ventral and dorsal roots of isolated spinal cords of infant mice. Interstitial potassium, [K+]o, and extracellular DC voltage were recorded from dorsal gray matter in some experiments. When oxygen was withdrawn, synaptically transmitted discharges (dorsal horn response, DHR, and monosynaptic ventral root reflex, VRR) began to be depressed within a minute, and were depressed to less than 30% of control amplitude in 10-15 min. Responses recovered fully if oxygen was readmitted within 45 min, but no recovery was seen after 90 min of hypoxia. The degree of the depression of VRR was as expected from the depression of the electrotonically conducted excitatory postsynaptic potential (VRepsp). Responses failed much more rapidly in spinal cords of 15-16-day-old mice, than of 9-14-day-olds. When the spinal cord was bathed in elevated [Ca2+]o or in reduced [Mg2+]o, synaptic transmission was consistently maintained for a longer period of hypoxia than in bathing fluid of normal cation content. In a sizeable minority of the trials during hypoxia an abrupt increase of [K+]o occurred, accompanied by a sudden negative shift of extracellular potential, closely resembling spreading depression (SD) of forebrain structures. Delayed post-hypoxic spontaneous activity was seen in many spinal cords. The results are compatible with the hypothesis that hypoxic failure of synaptic transmission is due, in part or whole, to blockade of inward Ca2(+)-current in presynaptic terminals. Cells in spinal gray matter can no longer be regarded as 'immune' to SD-like depolarization, but the limited conditions under which SD can occur are not yet clear.

Reversible effects of hypoxia on neurons in mouse dorsal root ganglia in vitro

Mouse dorsal root ganglia (DRG) were isolated and maintained in a tissue chamber. Membrane potential of 'A-type' neurons was recorded with intracellular electrodes. When the supply of oxygen was reduced, cells depolarized by a few mV and then maintained a stable membrane potential or partially repolarized. During depolarization the action potential was reduced in amplitude and the hyperpolarizing afterpotential was depressed. Reoxygenation within 15-88 min was followed by a brief period of hyperpolarization and then complete recovery. In about 60% of the cells, invasion of the cell soma by impulses triggered by dorsal root (DR) stimulation failed during hypoxia while action potentials could still be evoked by stimulation of the peripheral nerve and by direct intracellular stimuli. Conduction from DR into the peripheral nerve stump was unchanged indicating that the blockade of DR-evoked impulse conduction occurred at the bifurcation of the axon. Results with paired pulse stimulation indicated that impulses passing the axon bifurcation leave a long lasting (greater than or equal to 25 ms) post-spike subnormal period. In DRG cells treated with tetraethylammonium (TEA) the calcium-mediated 'shoulder' of the action potential was curtailed during oxygen withdrawal. In contrast to CNS neurons, DRG cells did not show early hypoxic hyperpolarization, nor the delayed hypoxic spreading depression-like depolarization. The findings support the suggestion that the reversible depression of synaptic potentials in the CNS during the early phase of hypoxia is caused by a combination of conduction failure at axon branch points and curtailment of voltage calcium currents of presynaptic terminals, both effects resulting in reduced transmitter output.

Sulfonylurea binding sites associated with ATP-regulated K+ channels in the central nervous system: autoradiographic analysis of their distribution and ontogenesis, and of their localization in mutant mice cerebellum

The localization of a putative ATP-regulated K+ channel in normal rat and neurological mutant mice was studied by light microscopic quantitative autoradiography using a tritiated glibenclamide, an antidiabetic sulfonylurea. Glibenclamide binding sites presented a heterogeneous distribution in the rat central nervous system. Their density was particularly important in substantia nigra reticulata, septohippocampal nucleus, globus pallidus, neocortex, molecular layer of cerebellum, CA3 field and dentate gyrus of hippocampus. Conversely hypothalamic areas, medulla oblongata and spinal cord contained only low amounts of glibenclamide receptors. The ontogenesis of sulfonylurea binding sites was a postnatal phenomenon and seemed to correlate with the maturation of neuronal connectivity. In the cerebellum of neurological mutant mice, the autoradiographic patterns were different to that of wild-type cerebellum. In particular, in the molecular layer of weaver cerebellum, a decrease of 82% of binding site density suggested a presynaptic position of glibenclamide receptors in parallel fibers.

Preservation of integrative function in a perfused guinea pig brain

The mammalian brain has been one of the most difficult organs to maintain using artificial perfusion. Normal biochemistry, histology, and electrophysiology of the brain have been demonstrated for limited periods in vitro, but it has been more difficult to maintain complex, integrative neuronal activity such as the electroencephalogram (EEG) or programmed motor output. Normal motor output, other than reflex activity, has not previously been demonstrated in a perfused brain preparation. This paper reports the first preservation of normal function in a complete motor network, including intact afferent and efferent pathways, during perfusion of the mammalian brain. The brain, rostral spinal cord and peripheral nervous system of the guinea pig were perfused in situ using an artificial blood containing the oxygen carrier, perfluorotributylamine (FC-43). This preparation was maintained normothermic, whereas many other perfused brain preparations have been maintained hypothermic to prolong viability. Survival was enhanced by the addition of HEPES buffer to the perfusion medium, probably by increasing carbon dioxide transport. The duration of normal EEG was extended to 8 h. Spontaneous respiratory motor output with normal waveform and temporal pattern was recorded from the phrenic nerve for an average of 6 h. The respiratory motor output responded appropriately to blood pCO2, temperature, blood flow, drug concentrations, and electrical stimulation of vagal afferent fibers. This preparation represents a significant advance in the ability to preserve neural function during perfusion, and should offer advantages for studying cellular electrophysiology of intact, functioning neural networks, as well as neurochemistry and neuropharmacology.

Effects of metabolic inhibition on the membrane properties of isolated mouse primary sensory neurones

1. The patch-clamp technique has been used to investigate the mechanisms that couple membrane excitability to metabolism in neurones isolated from mouse dorsal root ganglia. 2. Blockade of electron transport by cyanide (CN-), reduction of the mitochondrial membrane potential with carbonyl cyanide p-trifluoromethoxyphenyl hydrazone (FCCP), removal of glucose or inhibition of glycolysis with idoacetic acid (IAA), all increased a K+ conductance (gK), which could be sufficient to shunt action potentials. 3. The K+ conductance was reduced by incubation of cells in Ca2(+)-free solutions or by increasing the Ca2+ buffering power of pipette-filling solutions. The Ca2+ ionophore, ionomycin, also increased a K+ conductance, and current fluctuation analysis showed that the channels carrying the current induced by both ionomycin and by CN- had a similar mean conductance of circa 9 pS. Thus, increased gK was a Ca2(+)-dependent K+ conductance, gK(Ca), reflecting a rise in resting [Ca2+]i. 4. The conductance was not affected by inclusion of ATP or an ATP-regenerating system in the pipette, suggesting that the underlying rise in [Ca2+] is not due directly to loss of ATP, and confirming that the increased gK is not carried through ATP-dependent K+ channels. 5. Voltage-gated K+ currents evoked by membrane depolarization were increased by CN- or glucose removal. The current-voltage relation of the increased gK mirrored the voltage dependence of Ca2+ entry, and thus reflects impaired cellular handling of the Ca2+ load imposed by depolarization. 6. The rise in [Ca2+]i and altered Ca2+ buffering capacity induced by metabolic blockade affected several other conductances: (i) a Ca2(+)-dependent chloride current was increased. (ii) Both the low-threshold transient and high-threshold sustained voltage-gated Ca2+ currents were attenuated and their thresholds were shifted in the hyperpolarizing direction. (iii) The inward current activated by hyperpolarization. IH, seen in large cells, was attenuated by either metabolic blockade or ionomycin. 7. The responses of these neurones to impaired metabolism thus depend largely on the effects of raised [Ca2+]i on the populations of channels expressed by the cells. These changes in membrane properties could account for some of the changes in neuronal behaviour seen during the clinical states of hypoxia or hypoglycaemia, underlying changes in central nervous system function.

Effects of metabolic blockade on the regulation of intracellular calcium in dissociated mouse sensory neurones

1. Impaired intracellular Ca2+ concentration ([Ca2+]i) regulation may underlie alterations in neuronal function during hypoxia or hypoglycaemia and may initiate cell damage. We have used the Ca2(+)-sensitive fluorophore, Fura-2, to study the regulation of [Ca2+]i in neurones isolated from mouse dorsal root ganglia. Mean resting [Ca2+]i was 163 +/- 11 nM (mean +/- S.E.M., n = 38). 2. Depolarization by exposure to 20 or 30 mM-K+ caused a rapid Co2(+)- and Cd2(+)-sensitive rise in [Ca2+]i, which subsequently declined with a time course usually fitted by the sum of two exponential functions. 3. Interference with mitochondrial function (by CN- or FCPP) or with glycolysis (by glucose removal) all raised [Ca2+]i by up to 220%. Addition of FCCP in the presence of CN- further increased [Ca2+]i. The response to CN- was still seen in the absence of extracellular Ca2+, although it attenuated rapidly, indicating release from an intracellular store. 4. Either CN- or glucose removal increased the rise in [Ca2+]i induced by K+ 2- to 3-fold and slowed recovery, suggesting interference with sequestration or extrusion of [Ca2+]i. 5. Resting [Ca2+]i rose when external Na+ was replaced by Li+ or N-methyl-D-glucamine, demonstrating the presence of a Na(+)-Ca2+ exchange process. However, Na+ replacement had only a slight effect on the handling of a Ca2+ load. 6. We conclude that (i) Ca2+ is released into the cytoplasm from intracellular organelles when energy supplies are reduced: (ii) that the extrusion or sequestration of Ca2+ entering the cell during electrical activity is rapidly impaired by interference with mitochondrial metabolism: and (iii) Na(+)-Ca2+ exchange makes only a small contribution to intracellular Ca2+ homeostasis. 7. [Ca2+]i would thus be expected to rise in vivo during hypoxia or hypoglycaemia and may initiate alterations in neuronal function. However, if a rise in Ca2+ is an important cause of cell damage in cerebral hypoxaemia, the combination of excitation and hypoxia will lead to the largest increases in [Ca2+]i, while hypoxia alone appears to cause only a small increase in [Ca2+]i in quiescent cells.

Anoxia reveals a vulnerable period in the development of long-term potentiation

Transient anoxia occurring 1-2 min after high-frequency stimulation selectively prevented the stable expression of long-term potentiation (LTP). Anoxia occurring after this brief vulnerable period did not reverse LTP. Experiments on the duration of anoxia necessary to block LTP expression indicated that simply reducing synaptic transmission was insufficient but that membrane depolarization was not required. The effects of anoxia on LTP were blocked by antagonists of A1 adenosine receptors. It is concluded that LTP develops in about one minute and that the chemistries operating in this period are easily disrupted by an event triggered by adenosine receptors.

Acidosis and blockade of orthodromic responses caused by anoxia in rat hippocampal slices at different temperatures

1. Interstitial pH (pHo) and field responses (to stratum radiatum stimulation) were recorded simultaneously with double-barrelled microelectrodes in the CA1 region of hippocampal slices from Sprague-Dawley rats. 2. Both the relative acidity and amplitude of field responses increased with depth, reaching a maximum near the centre of the slice. When the temperature was raised from 22 to 37 degrees C, this pHo gradient was greater than 2 times steeper, but the field responses were much diminished. 3. Standard anoxic tests (substituting 95% N2 + 5% CO2 for 95% O2 + 5% CO2, for 2 min) tended to reduce pHo and population spikes, but these effects were highly temperature sensitive: at approximately 22 degrees C the blocking rate was only 12.3 +/- 4.6% and delta pHo -0.018 +/- 0.0157 units, both per minute; corresponding changes at 34-35 degrees C were 67.6 +/- 11.9% and -0.065 +/- 0.0046 units per minute. Highly significant linear correlations between rates of block and delta pHo gave a mean slope of 90.4 +/- 17.6% per 0.1 unit of acid change. 4. Anoxia caused similar temperature-dependent increases in acidity in stratum pyramidale and radiatum, but in the latter field responses (EPSPs) were much less depressed after 2 min of anoxia. 5. When slices were superfused with acid medium (low [HCO3-]), much greater reductions in pHo were needed to depress responses, giving a mean slope of 17.7% per 0.1 pH unit. 6. In glucose-free medium, there was a slow alkaline shift in pHo (0.13 +/- 0.036 units); population spikes and the acid transients evoked by anoxia disappeared. 7. It was concluded that acidosis cannot be the immediate cause of the similar depressions of postsynaptic excitability seen during anoxia and hypoglycaemia. 8. In further tests, DL-p-hydroxyphenyl-lactic acid, a blocker of lactate transport, failed to diminish acid transients evoked by anoxia, indicating that these are not mediated principally by lactate transport.

Potassium currents in hippocampal pyramidal cells

The hippocampal pyramidal cells provide an example of how multiple potassium (K) currents co-exist and function in central mammalian neurones. The data come from CA1 and CA3 neurones in hippocampal slices, cell cultures and acutely dissociated cells from rats and guinea-pigs. Six voltage- or calcium(Ca)-dependent K currents have so far been described in CA1 pyramidal cells in slices. Four of them (IA, ID, IK, IM) are activated by depolarization alone; the two others (IC, IAHP) are activated by voltage-dependent influx of Ca ions (IC may be both Ca- and voltage-gated). In addition, a transient Ca-dependent K current (ICT) has been described in certain preparations, but it is not yet clear whether it is distinct from IC and IA. (1) IA activates fast (within 10 ms) and inactivates rapidly (time constant typically 15-50 ms) at potentials positive to -60 mV; it probably contributes to early spike-repolarization, it can delay the first spike for about 0.1 s, and may regulate repetitive firing. (2) ID activates within about 20 ms but inactivates slowly (seconds) below the spike threshold (-90 to -60 mV), causing a long delay (0.5-5 s) in the onset of firing. Due to its slow recovery from inactivation (seconds), separate depolarizing inputs can be "integrated". ID probably also participates in spike repolarization. (3) IK activates slowly (time constant, tau, 20-60 ms) in response to depolarizations positive to -40 mV and inactivates (tau about 5s) at -80 to -40 mV; it probably participates in spike repolarization. (4) IM activates slowly (tau about 50 ms) positive to -60 mV and does not inactivate; it tends to attenuate excitatory inputs, it reduces the firing rate during maintained depolarization (adaptation) and contributes to the medium after-hyperpolarization (mAHP); IM is suppressed by acetylcholine (via muscarinic receptors), but may be enhanced by somatostatin. (5) IC is activated by influx of Ca ions during the action potential and is thought to cause the final spike repolarization and the fast AHP (although ICT may be involved). Like IM, it also contributes to the medium AHP and early adaptation. It differs from IAHP by being sensitive to tetraethylammonium (TEA, 1 mM), but insensitive to noradrenaline and muscarine. Large-conductance (BK; about 200 pS) Ca-activated K channels, which may mediate IC, have been recorded. (6) IAHP is slowly activated by Ca-influx during action potentials, causing spike-frequency adaptation and the slow AHP. Thus, IAHP exerts a strong negative feedback control of discharge activity.(ABSTRACT TRUNCATED AT 400 WORDS)

Galanin and Glibenclamide Modulate the Anoxic Release of Glutamate in Rat CA3 Hippocampal Neurons

The effects of brief anoxic episodes on intracellularly recorded CA3 pyramidal neurons have been studied in the hippocampal slice preparation. Anoxia induced a depolarization occasionally preceded by a transient hyperpolarization associated with a fall in input resistance. The anoxic depolarization was due to the release of glutamate from presynaptic terminals since it was blocked by tetrodotoxin (TTX) (1 microM) or by the broad spectrum excitatory amino acid antagonist kynurenate (1 mM). In the presence of TTX (1 microM) or kynurenate (1 mM), anoxia only induced a hyperpolarization which was due to activation of a K+ conductance. The anoxic depolarization was blocked by galanin, a hormone which activates ATP sensitive K+ (K+ATP) channels. Anoxic depolarization was increased by the potent sulfonylurea agent glibenclamide (GLIB) which blocks K+ATP channels. Bath applications of these agents had little effect when applied in oxygenated Krebs solution suggesting that their action may be mediated by K+ATP channels. Since excessive release of glutamate during anoxia is neurotoxic, agents such as galanin which activate K+ATP channels may provide tissue specific protection against anoxic damage.

Activators of ATP-sensitive K+ channels reduce anoxic depolarization in CA3 hippocampal neurons

In CA3 hippocampal neurons of the rat, brief anoxic episodes produce a depolarization which is probably due to a synaptic release of glutamate. Diazoxide, an activator of ATP-sensitive K+ channels (K+ ATP), blocks the anoxic depolarization and has no effect in control oxygenated artificial cerebrospinal fluid. The hormone somatostatin which activates K+ ATP channels in the pancreas also reduces the anoxic depolarization in CA3 neurons. We suggest that drugs that open K+ ATP channels may constitute a novel approach to selectivity reducing the deleterious effects of excessive release of glutamate during anoxia without producing a generalized blockade of glutamatergic synaptic transmission.

Membrane currents in hippocampal neurons

This chapter reviews properties and functions of endogenous ionic currents in hippocampal neurones. Currents considered are: Na currents INa(fast) and INa(slow); Ca currents; K currents--delayed rectifier IK(DR), transient IK(A), 'delay' current IK(D) and M current IK(M); inward rectifiers IQ, IK(IR) and ICl(V); Ca-activated currents IK(Ca) (IC and IAHP), ICl(Ca) and Ication(Ca); Na-activated currents; and anoxia-induced currents.

Anoxic changes in dentate granule cells

In most of the granule cells recorded, by current clamp and single-electrode voltage-clamp (SEVC), only small depolarizations (or inward currents) and minor conductance increases were observed during brief periods of anoxia (2-3 min). Thus, unlike pyramidal cells, granule cell bodies show little sign of K channel activation by anoxia. Post-anoxic hyperpolarizations were also minimal. Moreover, diazoxide (an activator of ATP-sensitive K conductance (GK(ATP]) had no consistent hyperpolarizing action. The depressant effect of diazoxide on anoxic glutamate release from mossy fibres is therefore likely to be mediated by GK(ATP) channels situated on granule cell axons or terminals rather than on the cell bodies.

Neurotoxicity at the N-methyl-D-aspartate receptor in energy-compromised neurons. An hypothesis for cell death in aging and disease

Our results demonstrated that the neurotoxicity of glutamate and closely related agonists was mediated by the NMDA receptor in rat cerebellar granule cells. Evidence was presented to support our hypothesis that the pivotal event in the transition of these EAAs from neurotransmitters to neurotoxins is relief of the voltage-dependent Mg++ block of the NMDA channel due to changes in membrane potential which can be caused by depletion of highly phosphorylated nucleotides or by other depolarizing stimuli. Persistent stimulation of NMDA receptors whose channels are unblocked by Mg++ can permit excessive influx of Na+ and Ca++ and neuronal death can follow by a mechanism not yet understood. Glutamate is not toxic at kainate receptors although they are present on these cells. These findings underline the potential importance of perturbations in energy metabolism in a variety of neurodegenerative disorders and in the normal process of aging which share the common feature of the loss of neurons.