Dependence of the viability of neurons in hippocampal slices on oxygen supply

An ex vivo model of an oligodendrocyte-directed T-cell attack in acute brain slices

Death of oligodendrocytes accompanied by destruction of neurons and axons are typical histopathological findings in cortical and subcortical grey matter lesions in inflammatory demyelinating disorders like multiple sclerosis (MS). In these disorders, mainly CD8+ T-cells of putative specificity for myelin- and oligodendrocyte-related antigens are found, so that neuronal apoptosis in grey matter lesions may be a collateral effect of these cells. Different types of animal models are established to study the underlying mechanisms of the mentioned pathophysiological processes. However, although they mimic some aspects of MS, it is impossible to dissect the exact mechanism and time course of ''collateral'' neuronal cell death. To address this course, here we show a protocol to study the mechanisms and time response of neuronal damage following an oligodendrocyte-directed CD8+ T cell attack. To target only the myelin sheath and the oligodendrocytes, in vitro activated oligodendrocyte-specific CD8+ T-cells are transferred into acutely isolated brain slices. After a defined incubation period, myelin and neuronal damage can be analysed in different regions of interest. Potential applications and limitations of this model will be discussed.

Intracisternal administration of glibenclamide or 5-hydroxydecanoate does not reverse the neuroprotective effect of ketogenic diet against ischemic brain injury-induced neurodegeneration

PRIMARY OBJECTIVE

To investigate the role of ATP-sensitive potassium (K(ATP)) channels in the neuroprotective effects of a ketogenic diet against cardiac arrest-induced cerebral ischemic brain injury-induced neurodegeneration.

RESEARCH DESIGN

Male Sprague Dawley rats were randomly divided into three groups and were fed with a ketogenic diet for 25 days before being subjected to a cardiac arrest-induced cerebral ischemia for 8 minutes 30 seconds. Four hours before cardiac arrest-induced cerebral ischemia, one group was intracisternally injected with glibenclamide, a plasma membrane K(ATP) channel blocker. The second group was injected with 5-hydroxydecanoate, a mitochondrial K(ATP) channel blocker. The third group was without the pre-treatment with K(ATP) channel antagonist. Nine days after the cardiac arrest, rats were sacrificed. Fluoro-jade (FJ) staining was used to evaluate cerebral ischemic neurodegeneration in the rat brain sections.

MAIN OUTCOMES AND RESULTS

The number of FJ-positive degenerating neurons in the CA1 area of the hippocampus, the cerebellum and the thalamic reticular nucleus of the ketogenic diet-fed rats with or without glibenclamide or 5-hydroxydecanoate pre-treatment before cardiac arrest-induced cerebral ischemia is zero.

CONCLUSIONS

The results suggest that K(ATP) channels do not play a significant role in the neuroprotective effects of the ketogenic diet against cardiac arrest-induced cerebral ischemic injury-induced neurodegeneration.

Prolyl hydroxylase domain inhibitors: a route to HIF activation and neuroprotection

Abstract Ischemic stroke is a major cause of death worldwide, and current therapeutic options are very limited. Preconditioning with an ischemic or hypoxic insult is beneficial in experimental models of ischemic stroke. Ischemia/hypoxia results in activation of numerous transcription factors, including hypoxia inducible factor (HIF), which is a master regulator of oxygen homeostasis. HIF activation induces a diverse range of target genes, encompassing a wide variety of cellular processes; including angiogenesis, energy metabolism, cell survival, radical production/scavenging, iron metabolism, stem cell homing, and differentiation. Inhibition of HIF prolyl hydroxylase domain (PHD) enzymes results in activation of HIF and is likely to mimic, at least in part, the effects of hypoxia preconditioning. A caveat is that not all consequences of HIF activation will be beneficial and some could even be deleterious. Nevertheless, PHD inhibitors may be therapeutically useful in the treatment of stroke. Prototype PHD inhibitors have shown promising results in preclinical models.

Collateral neuronal apoptosis in CNS gray matter during an oligodendrocyte-directed CD8(+) T cell attack

Demyelination and death of oligodendrocytes accompanied by transection of neurites and neuronal apoptosis are pathological hallmarks of cortical and subcortical gray matter lesions in demyelinating viral and autoimmune inflammatory CNS disorders. In these disorders, leukocortical lesions, containing the perikarya of most efferent neurons, display pronounced infiltration by CD8(+) T cells of putative specificity for oligodendrocyte- and myelin-related antigens. Hence, neuronal apoptosis in gray matter lesions may be a collateral effect of an oligodendrocyte-directed attack by CD8(+) T cells. To challenge this hypothesis, we transferred activated antigen-specific CD8(+) T cells (OT-I T cells) into acute coronal brain slices from mice selectively expressing ovalbumin as a cytosolic neo-self-antigen in oligodendrocytes (ODC-OVA mice). We studied mechanisms and kinetics of oligodendroglial and neuronal apoptosis in the neocortex and hippocampus, using multicolor staining for different cell types and activated caspase-3. Within the gray matter, a single OT-I T cell caused simultaneous caspase-3 activation in about 30 ODCs and 10 neurons within 6 h in a strictly antigen-dependent manner. Experiments with OT-I T cells genetically deficient for perforin or the granzyme B-cluster and with blocking anti-FasL antibodies as well as proinflammatory cytokines revealed, that collateral apoptosis of neurons was likely due to a spillover of perforin and granzyme(s) from the OT-I T cell itself or the immunological synapse that it selectively formed with antigen-presenting oligodendrocytes. Collateral neuronal apoptosis could contribute to substantial neuronal loss in gray matter lesions and cause persistent neurological impairment in both acute and chronic gray matter lesions in various inflammatory CNS disorders.

Optical assessment of motoneuron function in a “twenty-four-hour” acute spinal cord slice model from fetal rats

In acute slice preparations of most brain regions, neuronal functions are preserved for only few hours. Since the effects of growth factors or neurotoxic agents are often manifested beyond this time scale, corresponding studies are typically performed on cultured cells. However, cell cultures are generated and maintained under vastly different conditions that can grossly alter neuronal properties. For example, glutamate application to motoneuronal cultures has been reported to modulate neurite formation in some studies while in others it has been reported to kill cells. Here, we have examined whether acute spinal cord slices from rat fetuses can be used within a time window of 24 h for assessment of long-term effects of neuromodulators. In these slices, we have studied the action of glutamate on lumbar motoneurons loaded with fura-2 and rhodamine-123 to monitor intracellular Ca2+ ([Ca2+]i) and mitochondrial potential (Deltapsi), respectively. Further, loading with fura-2 or propidium iodide allowed for morphological assessment of cell viability and death, respectively. Pulses (15 s) or 1 h application of glutamate (300 microM) evoked a moderate (approximately 500 nM) [Ca2+]i rise, but no change of Deltapsi. Even after 24 h, no glutamate-induced cell death was observed and glutamate pulse-evoked [Ca2+]i transients were comparable to controls. The data demonstrate that glutamate does not deregulate [Ca2+]i homeostasis in fetal motoneurons in situ. We propose that acute spinal cord slices from perinatal rodents are a robust model that allows for analysis of neuronal properties and cell viability within a time window of at least 24 h.

Protective role of neuronal KATP channels in brain hypoxia

During severe arterial hypoxia leading to brain anoxia, most mammalian neurons undergo a massive depolarisation terminating in cell death. However, some neurons of the adult brain and most immature nervous structures tolerate extended periods of hypoxia-anoxia. An understanding of the mechanisms underlying this tolerance to oxygen depletion is pivotal for developing strategies to protect the brain from consequences of hypoxic-ischemic insults. ATP-sensitive K(+) (K(ATP)) channels are good subjects for this study as they are activated by processes associated with energy deprivation and can counteract the terminal anoxic-ischemic neuronal depolarisation. This review summarises in vitro analyses on the role of K(ATP) channels in hypoxia-anoxia in three distinct neuronal systems of rodents. In dorsal vagal neurons, blockade of K(ATP) channels with sulfonylureas abolishes the hypoxic-anoxic hyperpolarisation. However, this does not affect the extreme tolerance of these neurons to oxygen depletion as evidenced by a moderate and sustained increase of intracellular Ca(2+) (Ca(i)). By contrast, a sulfonylurea-induced block of K(ATP) channels shortens the delay of occurrence of a major Ca(i) rise in cerebellar Purkinje neurons. In neurons of the neonatal medullary respiratory network, K(ATP) channel blockers reverse the anoxic hyperpolarisation associated with slowing of respiratory frequency. This may constitute an adaptive mechanism for energy preservation. These studies demonstrate that K(ATP) channels are an ubiquituous feature of mammalian neurons and may, indeed, play a protective role in brain hypoxia.

Direct impact of T cells on neurons revealed by two-photon microscopy in living brain tissue

Encephalitogenic T cells invade the brain during neuroinflammation such as multiple sclerosis (MS), inducing damage to myelin sheaths and oligodendrocytes. Only recently, neuronal structures were reported to be a crucial target in the disease. Here, two-photon microscopy using ion-sensitive dyes revealed that within the complex cellular network of living brain tissue, proteolipid protein (PLP)-specific T cells and T cells recognizing the nonmurine antigen ovalbumin (OVA) directly and independently of the major histocompatibility complex (MHC) contact neurons in which they induce calcium oscillations. T cell contact finally resulted in a lethal increase in neuronal calcium levels. This could be prevented by blocking both perforin and glutamate receptors. For the first time, our data provide direct insight into the activity of T cells in the living brain and their detrimental impact on neurons.

Chemical anoxia activates ATP-sensitive and blocks Ca(2+)-dependent K(+) channels in rat dorsal vagal neurons in situ

The contribution of subclasses of K(+) channels to the response of mammalian neurons to anoxia is not yet clear. We investigated the role of ATP-sensitive (K(ATP)) and Ca(2+)-activated K(+) currents (small conductance, SK, big conductance, BK) in mediating the effects of chemical anoxia by cyanide, as determined by electrophysiological analysis and fluorometric Ca(2+) measurements in dorsal vagal neurons of rat brainstem slices. The cyanide-evoked persistent outward current was abolished by the K(ATP) channel blocker tolbutamide, but not changed by the SK and BK channel blockers apamin or tetraethylammonium. The K(+) channel blockers also revealed that ongoing activation of K(ATP) and SK channels counteracts a tonic, spike-related rise in intracellular Ca(2+) ([Ca(2+)](i)) under normoxic conditions, but did not modify the rise of [Ca(2+)](i) associated with the cyanide-induced outward current. Cyanide depressed the SK channel-mediated afterhyperpolarizing current without changing the depolarization-induced [Ca(2+)](i) transient, but did not affect spike duration that is determined by BK channels. The afterhyperpolarizing current and the concomitant [Ca(2+)](i) rise were abolished by Ca(2+)-free superfusate that changed neither the cyanide-induced outward current nor the associated [Ca(2+)](i) increase. Intracellular BAPTA for Ca(2+) chelation blocked the afterhyperpolarizing current and the accompanying [Ca(2+)](i) increase, but had no effect on the cyanide-induced outward current although the associated [Ca(2+)](i) increase was noticeably attenuated. Reproducing the cyanide-evoked [Ca(2+)](i) transient with the Ca(2+) pump blocker cyclopiazonic acid did not evoke an outward current. Our results show that anoxia mediates a persistent hyperpolarization due to activation of K(ATP) channels, blocks SK channels and has no effect on BK channels, and that the anoxic rise of [Ca(2+)](i) does not interfere with the activity of these K(+) channels.

Adenosine induces initial hypoxic-ischemic depression of synaptic transmission in the rat hippocampus in vivo

The present study was designed to investigate the role of adenosine in the hypoxic depression of synaptic transmission in rat hippocampus. An in vivo model of hypoxic synaptic depression was developed in which the common carotid artery was occluded on one side in the urethane-anesthetized rat. Inspired oxygen levels were controlled through a tracheal cannula. Rats were placed in a stereotaxic apparatus for stimulation and recording of bilateral hippocampal field excitatory postsynaptic potentials. The percent inspired oxygen could be reduced to levels that produced a reversible and repeatable depression of evoked synaptic transmission restricted to the hippocampus ipsilateral to the occlusion. Further reduction in the level of inspired oxygen depressed synaptic transmission recorded from both hippocampi. The adenosine nonselective antagonist caffeine and the A(1) selective antagonist 8-cyclopentyltheophylline prevented the initial depression in synaptic transmission. We conclude that the initial depression of synaptic transmission observed in the rat hippocampus in vivo is due to endogenous adenosine acting at neuronal adenosine A(1) receptors.

Cutting of living hippocampal slices by a highly pressurised water jet (macromingotome)

Living brain slices are usually cut with razor blades, which compress a ca. 50-microm-thick layer of tissue. This results in cell debris and lesioned cells which, e.g. form diffusion barriers between the bath and living neurons underneath, thereby prolonging response times of neurons to drugs in the bath saline and impeding the experimental access to intact neurons. To avoid such drawbacks, a macromingotome was developed which cuts nervous tissue with water jets. Physiological saline under pressures of 100-1800 bar was ejected through nozzles of 35-100 microm to cut 300-500-microm-thick hippocampal slices. Systematic variations of pressure and nozzle diameter revealed best results at 400-600 bar and with nozzle diameters of 60-80 microm. Under these conditions, intact CA1- and CA3-neurons as well as granule cells were detected with infrared microscopy at less than 10 microm underneath the surface of the slice. Superficial neurons with intact fine structures were also seen when the slices were studied by light-microscopy. Intra- and extracellular recordings from superficial neurons showed normal membrane- and full action potentials and the development of stable epileptiform discharges in 0 Mg(2+)-saline. These results indicate that the macromingotome offers an alternative way of cutting slices which may facilitate electrophysiological/neuropharmacological or fluorometric studies on superficial neurons.

Metabolism of the dorsal cochlear nucleus in rat brain slices

In vitro brain slices of the cochlear nucleus have been used for electrophysiological and pharmacological studies. More information is needed about the extent to which the slice resembles in vivo tissue, since this affects the interpretation of results obtained from slices. In this study, some chemical parameters of the dorsal cochlear nucleus (DCN) in rat brain slices were measured and compared to the in vivo state. The activities of malate dehydrogenase and lactate dehydrogenase were reduced in some DCN layers of incubated slices compared to in vivo brain tissue. The activities of choline acetyltransferase and acetylcholinesterase were increased or unchanged in DCN layers of slices. Adenosine triphosphate (ATP) concentrations for in vivo rat DCN were similar to those of cerebellar cortex. Compared with in vivo values, ATP concentrations were decreased in the DCN of brain slices, especially in the deep layer. Vibratome-cut slices had lower ATP levels than chopper-cut slices. Compared with the in vivo data, there were large losses of aspartate, glutamate, glutamine, gamma-aminobutyrate and taurine from incubated slices. These amino acid changes within the slices correlated with the patterns of release from the slices.

Ionic mechanisms underlying depolarizing responses of an identified insect motor neuron to short periods of hypoxia

Hypoxia can dramatically disrupt neural processing because energy-dependent homeostatic mechanisms are necessary to support normal neuronal function. In a human context, the long-term effects of such disruption may become all too apparent after a "stroke," in which blood-flow to part of the brain is compromised. We used an insect preparation to investigate the effects of hypoxia on neuron membrane properties. The preparation is particularly suitable for such studies because insects respond rapidly to hypoxia, but can recover when they are restored to normoxic conditions, whereas many of their neurons are large, identifiable, and robust. Experiments were performed on the "fast" coxal depressor motoneuron (Df) of cockroach (Periplaneta americana). Five-minute periods of hypoxia caused reversible multiphasic depolarizations (10-25 mV; n = 88), consisting of an initial transient depolarization followed by a partial repolarization and then a slower phase of further depolarization. During the initial depolarizing phase, spontaneous plateau potentials normally occurred, and inhibitory postsynaptic potential frequency increased considerably; 2-3 min after the onset of hypoxia all electrical activity ceased and membrane resistance was depressed. On reoxygenation, the membrane potential began to repolarize almost immediately, becoming briefly more negative than the normal resting potential. All phases of the hypoxia response declined with repeated periods of hypoxia. Blockade of ATP-dependent Na/K pump by 30 microM ouabain suppressed only the initial transient depolarization and the reoxygenation-induced hyperpolarization. Reduction of aerobic metabolism between hypoxic periods (produced by bubbling air through the chamber instead of oxygen) had a similar effect to that of ouabain. Although the depolarization seen during hypoxia was not reduced by tetrodotoxin (TTX; 2 microM), lowering extracellular Na+ concentration or addition of 500 microM Cd2+ greatly reduced all phases of the hypoxia-induced response, suggesting that Na influx occurs through a TTX-insensitive Cd2+-sensitive channel. Exposure to 20 mM tetraethylammonium and 1 mM 3,4-diaminopyridine increased the amplitude of the hypoxia-induced depolarization, suggesting that activation of K channels may normally limit the amplitude of the hypoxia response. In conclusion we suggest that the slow hypoxia-induced depolarization on motoneuron Df is mainly carried by a TTX-resistant, Cd2+-sensitive sodium influx. Ca2+ entry may also make a direct or indirect contribution to the hypoxia response. The fast transient depolarization appears to result from block of the Na/K pump, whereas the reoxygenation-induced hyperpolarization is largely caused by its subsequent reactivation.

Microcutting of living brain slices by a pulsed ultrafine water jet which allows simultaneous electrophysiological recordings (micromingotome)

Up to now microsurgical dissections in living nervous tissue (e.g. in slices or cell cultures) are performed either by micro-scalpels or by laser beams. As an alternative technique, a device for cutting with an ultrafine pulsed water jet was developed to allow precise, visually controled dissections in neuronal circuits even during electrophysiological recordings. Water is ejected by pressure (20-30 bar) from patch pipettes with tip diameters of 10-12 microm. By means of a piezo-element the pipette and the water jet are forced to oscillate vertically with a frequency of 200-400 Hz with an adjustable amplitude. These oscillations facilitate the transsection of neuronal connections even in thick slice preparations. Best results were obtained when the tip of the pipette was about 500 microm above the surface of the submerged slice tissue. This micromingotome offers the following advantages: (i) histological studies show that the water jet cleans the cutting surface, thus avoiding debris and its uncontrolable effects on cells underneath; (ii) the arrangement enables ongoing electrophysiological recordings from hippocampal slices during the cutting procedure and thus facilitates studies of the functions of neuronal connections; (iii) the device allows even disconnection in cultured nervous tissue overgrowing polyamid grids with 50 microm wide meshes.

Hibernation in ground squirrels induces state and species-specific tolerance to hypoxia and aglycemia: an in vitro study in hippocampal slices

Hibernation in mammals is associated with a regulated depression of global cellular functions accompanied by reductions of cerebral blood flow that would render the brain profoundly ischemic under normal conditions. Homeostatic control is preserved, however, and brain damage does not occur. We investigated the possibility that hibernation not only confers tolerance to profound hypothermia, but also to hypoxia and aglycemia independent of temperature. Hippocampal slices from ground squirrels Citellus tridecemlineatus in both the active and hibernating states and from rats were subjected to in vitro hypoxia and aglycemia at incubation temperatures of 36 degrees C, 20 degrees C, and 7 degrees C and evaluated histologically. A binary bioassay was used to determine the duration of hypoxia/aglycemia tolerated in each group. At all temperatures, slices from hibernating animals were most tolerant compared with both active squirrels and rats. Slices from active ground squirrels were more tolerant than rat at 20 degrees C and 7 degrees C but not at 36 degrees C indicating a species-specific difference that becomes manifest at lower temperatures. These results indicate that hibernation is associated not only with tolerance to profound hypothermia but also to deprivation of oxygen and glucose. Because tolerance was already demonstrable at the shortest duration of hibernation studied, rapid therapeutic induction of a similar state may be possible. Therefore, identification of the regulatory mechanisms underlying this tolerance may lead to novel neuroprotective strategies.

Hypothermia in hypoxic animals: mechanisms, mediators, and functional significance

A basic tenet of biology is that body temperature (Tb) has a marked effect on oxygen uptake of resting animals. For most animals, the temperature coefficient (Q10) is >> 2.5; e.g., resting oxygen uptake changes about 11% per degree C change in Tb. An important consequence of this dependence is that hyperthermia could be deleterious for hypoxic animals, particularly for oxygen sensitive organs, e.g., heart and brain. Conversely, a moderate degree of hypothermia could be beneficial during hypoxia. This concept is not new. Forced hypothermia is sometimes used in surgical procedures, particularly for heart and brain surgery. However, in many situations where hypothermia might have benefits, e.g., pediatric intensive care, it is not permitted. This is due in part to dogma and in part to the real and potential disadvantages of hypothermia, even in severely hypoxic animals. Among these in ventricular fibrillation. This is apparently preventable if blood pH is allowed to rise following the "Buffalo Curve." Another important disadvantage, were it to occur, is elevation of oxygen demand due to a thermogenic responses. However, at least in some species, the thermogenic response is blunted during hypoxia; e.g., in young rats. Furthermore, even if a thermogenic response occurs, this takes place primarily in muscles (shivering) and brown fat (non-shivering) and not in the O2-sensitive organs, heart and brain. A third disadvantage, for prolonged hypothermia, might be impairment of the immune response, a serious problem if hypoxia is combined with infection. This paper will review four aspects of behavioral fever and hypothermia: the occurrence among animals, the mechanisms and mediators that might trigger behavioral responses, and the functional significance.

A short period of hypoxia produces a rapid and transient rise in [K+]e in rat hippocampus in vivo which is inhibited by certain K(+)-channel blocking agents

Extracellular potassium concentrations, [K+]e, were measured in vivo in the rat dorsal hippocampus using valinomycin-based double-barrelled ion-selective microelectrodes. Experiments were conducted under chloral hydrate anaesthesia. The microelectrodes were implanted stereotaxically, after which different gas mixtures were administered by inhalation. Transient hypoxia was induced by changing the inspired gas from 20% O2/80% N2 to 10-0% O2/90-100% N2 for 0.5-2 min. Resting [K+]e in the dorsal hippocampus was 3.4 +/- 0.09 mM; 0.5, 1 or 2 min of 100% N2 administration caused a rapid rise of [K+]e to 0.75, 1.9 and 15 mM, respectively. Following 0.5 min of 100% N2, the switch back to 20% O2/80% N2 produced an almost instantaneous return to normal levels. The return of [K+]e to basal levels was more delayed after 1 or 2 min of 100% N2 inhalation. The rise of hippocampal [K+]e induced by hypoxia was influenced by body temperature, the increase being five-fold higher in rats whose body temperature was raised from 33 to 37 degrees C using a heating blanket. Three potassium-channel blocking agents, quinine, 4-aminopyridine and gliquidone, were tested for their action on the increase in [K+]e, induced by inhalation of 100% N2 for 0.5 min. Both 4-aminopyridine and quinine, administered systemically, attenuated the anoxia-induced rise in [K+]e by 70 and 35%, respectively. In contrast, gliquidone, given by intracerebroventricular injection, had no effect, suggesting that ATP-sensitive potassium channels are not involved in this very early change in [K+]e.

Morphology of CA3 neurons in hippocampal slices with nonepileptic and epileptic activity: a light and electron microscopic study

In guinea pig hippocampal slices, relations between morphology and spontaneous bioelectric activity of neurons were studied in control saline and with exposure to the epileptogenic drug pentylenetetrazole (PTZ) for 2-3 h. Light and electron microscopic structures of the CA3 region were analysed after recording the membrane potential. Neurons in slices kept in control saline exhibited spontaneous aperiodic bioelectric activities partly mixed with rhythmically occurring burst discharges. In slices exposed to PTZ, these periodic burst discharges and/or paroxysmal depolarization shifts (PDS) predominated. Light microscopic comparison focussing on tissue preservation showed no significant differences between control and PTZ-treated slices. Ultrastructural morphology revealed, on the one hand, no differences regarding spine and synaptic densities, and on the other hand, significantly more irregular electron translucent vacuoles within dendrites of PTZ-treated slices being either randomly distributed or clustered. The vacuoles are interpreted as early changes during epileptic activity.

Time dependent loss of tissue GABA content and immunoreactivity in hippocampal slices

Immunohistochemical detection of GABA was used to evaluate changes of the GABA innervation in hippocampal slices maintained in vitro. In parallel experiments the amount of GABA, glutamate and aspartate was measured with high performance liquid chromatography. The results showed that while glutamate and aspartate levels remained fairly constant, GABAergic neurons suffered remarkable alterations. During 8 hours' incubation the GABA content of the tissue and the number of GABA containing neuronal cell bodies decreased by 79.7% and 84.6%, respectively. The qualitative features of the immunoreactivity of the neuropil did not change. In conclusion, while in hippocampal slices tissue glutamate and aspartate levels are only slightly affected by the in vitro maintenance, more than half of the tissue GABA content is lost during prolonged in vitro incubation. As a consequence of the GABA loss, the ratio of endogenous inhibitory and excitatory amino acid transmitters has been altered, which could influence the viability of adult hippocampal tissue in vitro conditions.

N-methyl-D-aspartate receptor activation and Ca2+ account for poor pyramidal cell structure in hippocampal slices

The CA1 pyramidal cells appear damaged in micrographs of guinea pig hippocampal slices incubated in normal physiological buffer at 36-37 degrees C. This is remedied if slices are incubated in modified buffers for the first 45 min. Cell morphology is improved if this buffer is devoid of added Ca2+ and much improved if it contains N-methyl-D-aspartate (NMDA) receptor antagonists or 0 mM Ca2+ and 10 mM Mg2+. The cells then appear similar to CA1 pyramidal cells in situ. These findings support the notion that NMDA receptor activation and Ca2+, acting in the period immediately after slice preparation, permanently damage CA1 pyramidal cells in vitro.

Protein synthesis as a function of depth in slices of rat hippocampus

Physiologically viable slices of rat hippocampus were incubated in radiolabeled valine, then cut into 20 microns serial sections to evaluate the profile of protein synthesis through the depth of the slice. Maximum radiolabel incorporation was observed near the center of the slice, while at the upper (gas interface) and lower (liquid interface) surfaces radiolabel incorporation per section was reduced by about 30% and 90%, respectively. The results suggest that in properly slices damage due to slicing may be less important to cell viability than are limits on oxygen diffusion into the tissue.

Plasticity of identified neurons in slice cultures of hippocampus: a combined Golgi/electron microscopic and immunocytochemical study

The combined Golgi/electron microscope (EM) technique and immunocytochemistry for glutamate decarboxylase (GAD) were used to study the differentiation of pyramidal neurons and GABAergic inhibitory non-pyramidal cells in slice cultures of rat and mouse hippocampus. Golgi-impregnated and gold-toned cultures showed the characteristic curved structure of the Ammon's horn. Hippocampal regions CA1, CA3 and fascia dentata could easily be recognized. Pyramidal neurons in CA1 displayed all characteristics of this cell type known from Golgi studies in situ. A triangular cell body gives rise to a main apical dendritic shaft which gives off several side branches. Basal dendrites and the axon originate at the basal pole of the cell body. Apical and basal dendrites are densely covered with spines. As a characteristic feature of the cultured pyramidal cells, numerous spines were observed on the cell body. Most likely due to flattening of the slice during incubation, the pyramidal neurons in CA1 are no longer arranged in a densely packed layer. This results in more space between cell bodies which is filled in by numerous horizontal and basal dendrites originating from the pyramidal cell perikaryon. CA1 pyramidal neurons in slice cultures of the rat or mouse thus resemble the pyramidal neurons in the CA1 region of the primate hippocampus where a similar loose distribution of cell bodies is found. In the electron microscope, cell bodies and dendritic shafts of the gold-toned pyramidal cells formed symmetric synaptic contacts with presynaptic terminals. Numerous boutons were observed that established asymmetric synaptic contacts on gold-toned spines of peripheral pyramidal cell dendrites. This suggests that considerable synaptic reorganization takes place because in situ spines on peripheral dendritic segments are contacted mainly by extrinsic afferents. Like in situ, at least some of the terminals that establish symmetric synaptic contacts are GABAergic. In our immunocytochemical study we observed numerous GAD-positive terminals that formed a dense pericellular plexus around immunonegative cell bodies of pyramidal neurons. In the electron microscope these structures were identified as presynaptic boutons which formed symmetric synaptic contacts on cell bodies and dendritic shafts. They most likely originated from the GAD-positive neurons scattered in all layers of the slice culture. Our results have shown that the main cell types in the hippocampus, pyramidal neurons and GABAergic inhibitory non-pyramidal cells, survive and differentiate under the present culture conditions.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Actions of brain-protecting substances against both oxygen and glucose deprivation in the guinea pig hippocampal neurons studied in vitro

A study was made of the protective effects of several drugs (mannitol, phenytoin, vitamin E and dexamethasone) on the electrical activities of guinea pig hippocampal neurons in vitro when they were treated with a bathing medium deprived of both oxygen and glucose. Using guinea pig hippocampal slices, antidromic field potentials in the granular cell layer of the dentate gyrus were recorded stimulating mossy fibers. A model of ischemia in vivo in the slices was achieved by removing both oxygen and glucose from the perfusing medium. In standard medium, after 10 min of both oxygen and glucose deprivation, the field potentials exhibited minimum recovery with an amplitude of 6% of the control after 60 min. The protective effect of the drugs was evaluated by recovery of the field potential amplitude of the 60 min post-deprivation response and histological examination of the brain slice tissue. Drugs were added during 30 min of pre-deprivation and during deprivation. In this experiment we demonstrated that (1) phenytoin and vitamin E clearly showed protective action against neuronal damage caused by both oxygen and glucose deprivation in guinea pig hippocampal slices, (2) combined application of these drugs was more effective, and (3) mannitol showed no protective action in vitro. It was also demonstrated that (4) the dentate antidromic field response can be a useful index of cell death.

Model calculations of oxygen supply to tissue slice preparations

Excised tissue slice preparations are widely used in experimental medicine, pharmacology and physiology. Since slices are separated from the vascular system they have to be supplied with oxygen from the bath solution in which the slices are fixed. Otto Warburg designed a simple model of oxygen diffusion in such a tissue preparation. His model does not utilise some important parameters which may influence the oxygen distribution in the tissue: Unstirred bathing, non-vital superficial layers of tissue slices, damage by the cutting procedure and the influence of volume fraction and tortuosity over the oxygen supply. A compartment model has been designed to test how these parameters affect the oxygen distribution in tissue slices. The calculations have shown that all parameters may considerably affect the oxygen supply to tissue slices. Therefore, they have to be considered in the analysis of oxygen distribution and consumption in tissue slice preparations.

Adenosine antagonists delay hypoxia-induced depression of neuronal activity in hippocampal brain slice

Submerged rat hippocampal slices were exposed to hypoxic medium prepared with 95% N2/5% CO2. The population spikes recorded from CA1 cell layer were completely blocked within a range of 5-10 min. The adenosine antagonist theophylline (100 microM) delayed and partially prevented the hypoxia-induced depression. Increasing concentrations of the more potent adenosine antagonist 8-phenyltheophylline (8-PT; 0.1, 1, 10 microM) resulted in progressively less hypoxia-induced depression. The antidromically elicited afterpotentials recorded in the absence of synaptic transmission in low calcium, high magnesium medium were blocked within 8 min of hypoxia. Theophylline (100 microM) and 8-PT (10 microM) delayed to a similar extent the hypoxia-induced depression of the first afterpotential but did not prevent its complete depression.

Selective vulnerability of synaptic transmission in hippocampus to ex-vivo ischemia: effects of extracellular ionic substitution in the postischemic period

After 10-60 min of normothermic complete ischemia, hippocampal slices were prepared and allowed to recover for 60 min. The presence or absence of an evoked transsynaptic response was measured in CA1, CA3, and dentate gyrus. A selective vulnerability of the field excitatory postsynaptic potential to ischemia was found (CA1 greater than CA3 greater than dentate gyrus). Recovery of synaptic transmission in CA1 and CA3 was significantly improved by decreasing extracellular Ca2+ and increasing Mg2+ after ischemia. Addition of an N-methyl-D-aspartate antagonist further improved functional recovery. Postischemic reduction in extracellular Cl- increased recovery in CA1 and CA3, whilst reduction in Na+ was deleterious.

gamma-Aminobutyric acid-induced ion movements in the guinea pig hippocampal slice

gamma-Aminobutyric acid (GABA)-induced regional changes of extracellular Cl, K and Na concentration ([Cl]o, [K]o, [Na]o), as well as of the extracellular space were measured with ion-sensitive microelectrodes in guinea pig hippocampal slices. Microdrop application of GABA to the pyramidal cell layer of CA3 or CA1 induced a decrease of [Cl]o, while application to the dendritic layer of CA3 or CA1 induced an increase of [Cl]o in addition. All changes of [Cl]o persisted in the presence of TTX and were blocked by bath-applied bicuculline. The GABA-induced decrease of [Cl]o was reduced by bicuculline application to the pyramidal cell layer. The increase of [Cl]o was blocked by bicuculline application to the dendritic layer. Additionally, GABA induced an increase of [K]o and decreases/increases of [Na]o. Changes of [Cl]o, [K]o and [Na]o together were approximately electroneutral. [Cl]o increases were exaggerated and [Cl]o decreases partly masked by shrinkage of the extracellular space after GABA application. Changing [K] in the superfusate transiently changed GABA-induced [Cl]o movements in a way predicted from a change in driving force due to the effect of [K] on membrane potential. Then a partial recovery followed towards the original [Cl]o change. We conclude that inward and outward Cl transports maintain [Cl]i below equilibrium in CA3 and CA1 pyramidal somata and above equilibrium in CA3 and CA1 dendrites. The significance of this Cl-distribution for hippocampal inhibition is discussed.

Characterization of input synapses on intracellularly stained neurons in hippocampal slices: an HRP/EM study

This study describes the fine structure of input synapses on identified neurons in slices of the guinea pig hippocampus. For morphological identification, granule cells of the fascia dentata and pyramidal neurons of regio inferior of the hippocampus were impaled and intracellularly stained with horseradish peroxidase (HRP). Input synapses on the HRP-stained neurons were identified in the electron microscope by the location of the synapses in inner or outer zones of the dentate molecular layer, as in the case of the synaptic contacts on injected granule cells, or by unique fine structural characteristics, as in the case of the giant mossy fiber boutons on CA3 pyramidal cells. As in tissue fixed in situ by transcardial perfusion, a large number of terminals arising from the different afferents in inner and outer zones of the dentate molecular layer were well preserved and formed synaptic contacts with small spines, large complex spines, and dendritic shafts of the HRP-filled granule cells. Mossy fiber synapses on the stained CA3 neurons were densely filled with clear vesicles, contained a few dense-core vesicles, and formed synaptic contacts with large spines or excrescences. Occasionally electrondense degenerating boutons were also found impinging on the stained dendrites and spines. The significance of the present findings for electrophysiological and pharmacological studies on brain slices is discussed.

Rat hippocampal slices 'in vitro' display spontaneous epileptiform activity following long-term organotypic culture

Organotypic cultures of rat hippocampal slices were maintained for periods of up to 12 weeks in vitro. Cultures adopted a two-dimensional architecture whilst retaining the subfields characteristic of intact hippocampal slices. Coventional intracellular onset of spontaneous long-lasting epileptiform activity. Epileptiform activity characteristic of both interictal and ictal events (paroxysmal depolarising shifts, tonic/clonic phases and afterdischarges) was observed in the absence of pharmacological manipulation or of orthodromic stimulation. Epileptiform activity was abolished in the presence of high Mg2+ concentration or tetrodotoxin, agents known to block synaptic transmission. In addition, the frequency of epileptiform events was independent of membrane potential and the amplitude of the paroxysmal depolarising shift (PDS) displayed a near linear relationship with membrane potential. The PDS could be reversed at potentials approaching synaptic equilibrium potential. The N-methyl-D-aspartate (NMDA)-receptor antagonist DL-2-amino-5-phosphonovalerate (DL-APV) dose-dependently reduced both the amplitude and duration of the spontaneous paroxysmal shift, having no effect on the initiation of the event or the resting membrane parameters of the neurone. DL-APV also attenuated a late component of the synaptically evoked excitatory postsynaptic potentials (epsp) not observed in non-epileptiform neurones. Application of GABAA receptor antagonists bicuculline or picrotoxin converted interictal events to ictus. In the presence of these agents, ictal events were up to 90 s in duration. These results suggest that long-term culturing of hippocampal explants leads to an alteration in the balance of excitatory and inhibitory synaptic activity. This allows the expression of an excitatory amino acid depolarisation acting through NMDA receptors which contributes to the generation and maintenance of spontaneous epileptiform activity which is synaptic in origin.

Synaptic organization of intracellularly stained CA3 pyramidal neurons in slice cultures of rat hippocampus

Pyramidal cells of regio inferior in slice cultures of the rat hippocampus were impaled and intracellularly stained with horseradish peroxidase. A correlated light- and electron-microscopic analysis was then performed to study the properties of these neurons under culture conditions with particular emphasis on input synapses onto these cells. Like pyramidal cells in situ, CA3 pyramidal neurons in slice cultures had a triangular cell body with an apical stem dendrite emerging from it. Several basal dendrites and the axon arose from the basal pole of the cell body. The peripheral thin branches of both apical and basal dendrites were covered with small spines, whereas proximal thick dendritic segments and portions of the cell body exhibited large spines or excrescences. The axon gave off numerous fine varicose collaterals which projected to stratum radiatum of CA1 (Schaffer collaterals), to the alveus and to the hilar region. In one case a collateral could be followed to stratum moleculare of the fascia dentata. Electron-microscopic analysis of the injected pyramidal neurons revealed that their cell bodies, dendritic shafts and spines formed synaptic contacts with presynaptic terminals. Mossy fiber endings were identified by their large size and their numerous clear synaptic vesicles with some dense-core vesicles intermingled, and were observed to form synaptic contacts on the large spines or excrescences. Since extrinsic afferents degenerate in slice cultures, the numerous synaptic boutons on the identified pyramidal neurons probably arise from axons of intrinsic neurons that have sprouted in response to deafferentation. This assumption is supported by the finding that collaterals of the injected neurons formed abundant synaptic contacts on dendritic shafts and spines of other cells. These results suggest that, although pyramidal cells under culture conditions retain a remarkable number of their normal characteristics, considerable synaptic reorganization does take place.

Pitfalls in the use of brain slices

In vitro brain slices are the preparation of choice for the detailed examination of local circuit properties in mammalian brain. However it is the investigator's responsibility to verify that the circuits under investigation are indeed confined within the boundaries of the functional region of the slice used. The medium in which the slice is maintained is under the full control of the investigator. This places the burden on the investigator to ensure that: (1) the properties of the medium are fully under control; (2) the effects of the medium on the slice are known; (3) the conditions under which the slice is being maintained bear some reasonable relation to those it enjoys (or endures) in vivo. Generalizations to in vivo conditions must be made with caution. If at all possible, similar studies (perhaps less extensive, due to the greater technical difficulties) should be done in vivo to provide a basis for comparison. Investigators using drugs should be aware of, and respect, the basic pharmacological principles cited in the text. In particular, the substantial freedom the investigator has in defining the extracellular medium should not be abused.

Extracellular potassium ion activity and electrophysiology in the hippocampal slice: paradoxical recovery of synaptic transmission during anoxia

The relationship between extracellular potassium ion activity and neuronal excitability during anoxia was investigated in hippocampal slices in vitro. Extracellular field potentials and K+ activity were measured with double-barreled ion-selective microelectrodes placed either in the stratum pyramidale or stratum radiatum of field CA1. Orthodromic spike activity of CA1 pyramidal cells and field excitatory postsynaptic potentials (f-EPSPs) failed rapidly after anoxia with little change in potassium ion activity and without failure of the Schaffer collateral prevolley or antidromic responses of pyramidal cells. As [K+]o approached 8-10 mM, f-EPSPs and orthodromic spike activity recovered spontaneously. Continued anoxia resulted in massive release of K+ into the extracellular space and complete electrical silence. Presynaptic activity and antidromically elicited spike activity recovered promptly upon reoxygenation after anoxia, but synaptic transmission remained blocked for many minutes. Spontaneous recovery of f-EPSPs and spike activity suggests that a simple mechanism involving depolarization or hyperpolarization of neuronal elements cannot account for failure of synaptic transmission observed during anoxia. However, continued elevation of [K+]o and the associated loss of pre- and postsynaptic excitability with more prolonged anoxia indicated that depolarization was responsible for the eventual electrical silence as anoxia progressed.

Ketamine protects hippocampal neurons from anoxia in vitro

Ketamine, a dissociative, general anesthetic, blocks the excitation produced by activating one class of excitatory amino acid receptors, the N-methyl-D-aspartate receptor in the rat. We have found that ketamine can protect hippocampal neurons in culture and slice from anoxia. When added to cultures immediately prior to anoxic exposure, ketamine prevented the neuronal destruction seen after a day of anoxia. Neurons appeared undamaged and had normal resting and action potentials. Adenosine triphosphate levels in ketamine-protected anoxic cultures were approximately two-thirds of normal controls. Ketamine also prevented the irreversible loss of the population spike seen in hippocampal slices after prolonged perfusion with anoxic buffer. These results suggest that ketamine may have therapeutic potential in preventing anoxic damage from stroke in man.

Blockade of excitatory amino acid receptors protects anoxic hippocampal slices

Experiments in a variety of preparations have indicated that excessive activation of receptors for the excitatory amino acids glutamate and aspartate may mediate irreversible anoxic neuronal injury. We investigated this hypothesis in the in vitro hippocampal slice. Rat hippocampal slices perfused for 40 min with buffer equilibrated with 95% nitrogen/5% carbon dioxide lost their extracellular CA1 population spikes and failed to recover after prolonged reoxygeneration. It was impossible to locate cells with normal physiological properties in these anoxic slices with standard intracellular recording techniques. However, when excitatory transmission was blocked during anoxia with either high concentrations of magnesium or antagonists of excitatory amino acids (kynurenate or aminophosphonovalerate), the population spike returned to preanoxia levels. Intracellular recording showed that neurons in these protected slices had normal resting potentials, action potentials, and input resistances. These experiments provide additional support for the involvement of excitatory amino acids and their receptors in anoxic neuronal injury.

Effects of tissue preincubation and hypoxia on CA3 hippocampal neurons in the in vitro slice preparation

Using the in vitro hippocampal slice preparation, we studied the electrophysiological properties of pyramidal cells in tissue that was 'preincubated' (2-6 h in a large, static volume of oxygenated bathing medium) before being placed in an interface chamber for study. Striking differences were found in 'preincubated' vs 'non-preincubated' CA3 cells. The preincubated cells had more negative resting potentials, higher input resistance, lower threshold for stimulus-evoked burst discharge and larger hyperpolarizing afterpotentials. Cells in the preincubated CA3 region were also more likely to show spontaneous synchronized burst discharge, but were relatively resistant to hypoxia-induced spreading depression. CA1 cells were less dramatically affected by preincubation, showing little difference from their non-preincubated counterparts. Possible mechanisms involved in the CA3 preincubation effect, including glial buffering alterations and changes in Na+, K+-ATPase activity, are discussed.

Electrophysiological correlates of peroxide damage in guinea pig hippocampus in vitro

To study the effects of active oxygen on neuronal electrophysiology, hippocampal brain slices were exposed to hydrogen peroxide plus ferrous sulfate which react to produce hydroxyl free radicals. Analysis of extracellularly recorded somatic and dendritic responses to orthodromic stimulation indicated a decrease in both synaptic efficacy and impairment of action potential generation.

Metabolic stability of hippocampal slice preparations during prolonged incubation

Hippocampal slices were prepared under three conditions: (1) in medium containing glucose and oxygen at 4 degrees C; (2) as in (1), but at 37 degrees C; (3) in medium devoid of glucose and oxygen at 37 degrees C. The rates of recovery to roughly steady-state levels and through 8 h of incubation were monitored for energy metabolite levels and related parameters. In vitro stable values are compared with in situ hippocampal levels. Regardless of the conditions under which slices were prepared, metabolite levels required up to 3 h to stabilize, and these levels were maintained or improved through 8 h of incubation. Further, the maximal concentrations of metabolites were independent of the conditions of slice preparation. Total adenylates and total creatine levels reached 55% of those in vivo. Lactate decreased from the decapitation-induced high levels, but stabilized at concentrations about twice those in rapidly frozen brain. Cyclic AMP and cyclic GMP exhibited peak levels at 30 min of incubation, and cyclic GMP remained elevated for 3 h. Although all three methods of slice preparation resulted in similar metabolite profiles on incubation, the initial decreases in high energy phosphates were delayed by chilling. Most striking, the slices prepared in the absence of glucose and oxygen exhibited much smaller orthodromic evoked potentials in the dentate gyrus. The presence of glucose and oxygen during preparation of the slices appears to be critical to the electrophysiological response of the tissue.