Bismuth tracing in organotypic cultures of rat hippocampus

Bismuth is known to have neurotoxic side effects in humans and animals. In the 1970s France experienced about a thousand cases of patients suffering from bismuth-induced encephalopathy. Studies suggest that bismuth may provoke a selective degeneration of CA1 pyramidal cells in the organotypic cultures of rat hippocampus. A currently established technique for the histochemical visualization of bismuth was applied on hippocampal tissue cultures allowing the tracing of bismuth in concentrations hitherto not possible. The accumulation and subcellular localization of bismuth is demonstrated in the tissue cultures of rat hippocampus. CA1 pyramidal cells in the rat hippocampus exhibit the highest uptake of bismuth. High bismuth citrate concentrations (10 microM) are able to totally destroy the cytoarchitecture of the hippocampus. At ultrastructural levels bismuth was found to be located exclusively in lysosome-like organelles.     

Selective sparing of hippocampal CA3 cells following in vitro ischemia is due to selective inhibition by acidosis

A brief global ischemic insult to the brain leads to a selective degeneration of the pyramidal neurons in the hippocampal CA1 region while the neurons in the neighbouring CA3 region are spared. The reason for this difference is not known. The selective vulnerability of CA1 neurons to ischemia can be reproduced in vitro in murine organotypic slice cultures, if the ion concentrations in the medium during the anoxic/aglycemic insult are similar to that in the brain extracellular fluid during ischemia in vivo. As acidosis develops during ischemia, we studied the importance of extracellular pH for selective vulnerability. We found that cell death in the CA1 and CA3 regions was equally prevented by removal of calcium from the medium or following blockade of the N-methyl-D-aspartate (NMDA) receptor by D-2 amino-5-phosphonopentanoic-acid (D-APV). On the other hand, damage to the CA3 neurons markedly decreased with decreasing pH following in vitro ischemia, while the degeneration of CA1 neurons was less pH dependent. Patch-clamp recordings from pyramidal neurons in the CA1 and CA3 regions, respectively, revealed a pronounced inhibition of NMDA-receptor mediated excitatory postsynaptic currents (EPSCs) at pH 6.5 that was equally pronounced in the two regions. However, when changing pH from 6.5 to 7.4 the recovery of the EPSCs was significantly slower in the CA3 region. We conclude that acidosis selectively protects CA3 pyramidal neurons during in vitro ischemia, and differentially affects the kinetics of NMDA receptor activation, which may explain the difference in vulnerability between CA1 and CA3 pyramidal neurons to an ischemic insult.     

Selective destruction of mossy fibers and granule cells with preservation of the GABAergic network in the inferior region of the rat hippocampus after colchicine treatment

Lesions induced by colchicine injection into the rat hippocampus were investigated by means of electron microscopy and GABA immunocytochemistry. Granule cells were nearly completely destroyed 3 days after colchicine injection; since the necrosis of their axonal endings was delayed, an anterograde degeneration of the mossy fibers had probably taken place. The selectivity of the lesions was not limited to granule cells, for some pyramidal neurons in CA1 pyramidal layer were damaged. It was, however, striking to observe that throughout the hippocampal structure GABAergic neurons were spared from the effects of colchicine. For instance, GABAergic neurons were found in the vicinity of the completely destroyed granule cell layer. GABAergic neurons and terminals were also present in the CA3 region where the GABA-containing terminals formed a dense network of synapses with somata and dendrites of pyramidal cells. It was interesting to note that, consistent with previous studies, the GABAergic neurons in CA3 are innervated by mossy fibers. We conclude that after colchicine treatment the destruction of the granule cells was not associated with a lesion of the GABAergic network. This selective lesion provides a useful model with which to study the properties of CA3 neurons deprived of their major excitatory input but with an intact inhibitory network.     

The hippocampal CA3 network: An in vivo intracellular labeling study

The intrahippocampal distribution of axon collaterals of individual CA3 pyramidal cells was investigated in the rat. Pyramidal cells in the CA3 region of the hippocampus were physiologically characterized and filled with biocytin in anesthetized animals. Their axonal trees were reconstructed with the aid of a drawing tube. Single CA3 pyramidal cells arborized most extensively in the CA1 region, covering approximately two-thirds of the longitudinal axis of the hippocampus. The total length of axon collaterals in the CA3 region was less than in CA1 and the axon branches tended to cluster in narrow bands (200–800 μm), usually several hundred microns anterior or posterior to the cell body. The majority of the recurrent collaterals of a given neuron remained in the same subfield (CA3a, b, or c) as the parent cell. CA3a neurons innervated predominantly the basal dendrites, whereas neurons located proximal to the hilus (CA3c) terminated predominantly on the apical dendrites of both CA1 and CA3 cells. Two cells, with horizontal dendrites and numerous thorny excrescences at the CA3c–hilus transitional zone, were also labeled and projected to both CA3 and CA1 regions. All CA3 neurons projected some collaterals to the hilar region. Proximal (CA3c) neurons had numerous collaterals in the hilus proper. One CA3c pyramidal cell in the dorsal hippocampus sent an axon collateral to the inner third of the molecular layer. CA3c pyramidal cells in the ventral hippocampus had extensive projections to the inner third of the dentate molecular layer, as well as numerous collaterals in the hilus, CA3, and CA1 areas, and several axon collaterals penetrated the subiculum. The total projected axon length of a single neuron ranged from 150 to 300 mm. On the basis of the projected axon length and bouton density (mean interbouton distance: 4.7 μm), we estimate that a single CA3 pyramidal cell can make synapses with 30,000–60,000 neurons in the ipsilateral hippocampus. The concentrated distribution of the axon collaterals (“patches”) indicates that subpopulations of neurons may receive disproportionately denser innervation, whereas innervation in the rest of the target zones is rather sparse. These observations offer new insights into the physiological organization of the CA3 pyramidal cell network. © 1994 Wiley-Liss, Inc.     

GABA-dependent generation of ectopic action potentials in the rat hippocampus

Intracellular recordings from CA3 pyramidal cells of rat hippocampus in a slice preparation revealed the occurrence of interictal epileptiform discharges and synchronous GABA-mediated potentials during application of 4-aminopyridine (4AP, 50 μm ). The synchronous GABA-mediated potential consisted of a sequence of early hyperpolarization, long-lasting depolarization (LLD), and late hyperpolarization. Action potentials of variable amplitude occurred at the peak of the early hyperpolarization and during the LLD rising phase (48 of 64 cells); they were not prevented by membrane hyperpolarization and displayed inflections that were reminiscent of the initial segment-somatodendritic (IS-SD) fractionation. Interictal discharges were blocked by excitatory amino acid receptor antagonists, while both GABA-mediated potentials and action potentials of variable amplitude continued to occur (n = 10). The latter events were still recorded in the presence of the GABA_B receptor antagonist CGP-35348 (0.5–1 mm , n = 4), but were abolished by the GABA_A receptor antagonist bicuculline methiodide (BMI, 10 μm , n = 5). Localized application of BMI (20 μm , n = 6) or tetrodotoxin (TTX, 5 μm , n = 3) to the CA1 stratum radiatum blocked the variable amplitude action potentials; these effects were not seen when BMI (n = 4) or TTX (n = 4) were applied to the CA3 stratum radiatum, although both procedures made LLDs disappear. Our findings indicate that action potentials of variable amplitude recorded from CA3 pyramidal cells in the 4AP model are generated at or near the terminal region of the Schaffer collaterals and that they represent TTX-sensitive ectopic events. These action potentials are generated at this site by a BMI-sensitive (and thus GABA_A-mediated) mechanism. We propose that the ectopic action potentials reflect an increased excitability of axon terminals that is presumably caused by [K⁺]_o elevations associated with the 4AP-induced synchronous GABA-mediated potential.     

Development and selective neurodegeneration in cell cultures from different hippocampal regions

Previous studies have shown that pyramidal neurons in hippocampal regions CA1 and CA3 are selectively vulnerable in several neurodegenerative disorders and that a subpopulation of pyramidal neurons in cell cultures of embryonic hippocampus are sensitive to glutamate neurotoxicity. In order to determine whether the patterns of cell loss seen in situ correlate with intrinsic differences in neuronal sensitivities to glutamate-induced degeneration acquired during development, we characterized cultures established from different regions of postnatal rat hippocampus and then examined neuronal sensitivity to glutamate. Tissue corresponding to the dentate gyrus (DG) and regions CA1, CA2 and CA3 of Ammon's horn was removed by microdissection from transverse hippocampal slices and was used to establish cultures of dissociated cells. Cultures from all 4 regions contained 3 major morphological classes of neurons; pyramidal-like, bipolar and stellate. Pyramidal-like neurons comprised the majority of neurons in all cultures; these neurons extended one long and branching axon, and one or more short dendrites. Immunocytochemistry showed that all neurons possessed high levels of glutamate-like and gamma-aminobutyric acid (GABA)-like immunoreactivity when grown in isolation. In contrast, when bipolar and pyramidal neurons were cultured in contact with glial cells, glutamate and GABA immunoreactivity were selectively reduced in the bipolar and pyramidal cells, respectively, suggesting that cell interactions influence neurotransmitter phenotype. Subpopulations of hippocampal neurons from each hippocampal region were vulnerable to glutamate-induced neurotoxicity. Bipolar and stellate cells were resistant to glutamate, while pyramidal-like neurons showed varying degrees of sensitivity to glutamate depending upon which region they were taken from. Experiments with specific glutamate receptor agonists and antagonists demonstrated that both non N-methyl-D-aspartic acid (NMDA) receptors and NMDA receptors mediated glutamate-induced degeneration. There were clear differences in the vulnerability of the pyramidal-like neuron populations in cultures from the different hippocampal regions. The rank order of the vulnerability of pyramidal-like neurons to glutamate-induced neurodegeneration between regions in culture was: DG less than CA2 less than CA3 less than CA1. This pattern of selective vulnerability in cell culture corresponds directly to the pattern of selective cell loss seen in situ in Alzheimer's disease, epilepsy, and stroke suggesting that intrinsic neuronal differences in glutamate sensitivity may be involved in these disorders.     

Effects of GABA and baclofen on pyramidal cells in the developing rabbit hippocampus: an 'in vitro' study

Using the in vitro hippocampal slice preparation, we have investigated the effects of gamma-aminobutyric acid (GABA) and its analogue beta-(p-chlorophenyl)-GABA (baclofen) on CA1 and CA3 pyramidal cells in the developing rabbit hippocampus. Somatic applications: both GABA and baclofen, when applied to CA1 pyramidal cells from immature tissue, led to cell depolarization from resting membrane potential; this baclofen depolarization may be indirectly mediated. In contrast, CA3 pyramidal cells at the same age were primarily hyperpolarized by both drugs. In mature tissue, both GABA and baclofen applied at the soma induce cell hyperpolarizations. Dendritic applications: immature CA1 cells responded to dendritic GABA and baclofen application with depolarizations associated with increased cell excitability; here, too, the baclofen depolarization may be due to indirect 'disinhibition'. Both depolarizing and hyperpolarizing responses were recorded in immature tissue when GABA was applied to CA3 pyramidal cell dendrites: baclofen produced only hyperpolarizations. In mature CA1 cells, dendritic GABA application produced membrane depolarization, but dendritic baclofen application produced hyperpolarizations. In mature CA3 cells, dendritic GABA and baclofen application produced predominant hyperpolarizations. Mature CA1 pyramidal cells appear to retain some of the GABA-induced depolarizations characteristic of immature tissue. In contrast, mature CA3 neurons show only hyperpolarizing responses to GABA and baclofen application. In all cases, responses to GABA and baclofen are associated with a decrease in cell input resistance. We conclude that the GABAergic receptor/channel complexes mature differently in the CA1 and CA3 regions of the hippocampus.     

Escalating dose-multiple binge methamphetamine exposure results in degeneration of the neocortex and limbic system in the rat

Abuse of stimulant drugs such as methamphetamine (METH) and cocaine has been associated with long-lasting persistent behavioral alterations. Although METH-induced changes in the striatal dopaminergic system might play a role in these effects, the potential underlying neuroanatomical substrate for the chronic cognitive dysfunction in METH users is unclear. To investigate the involvement of non-dopaminergic systems in the neurotoxic effects of METH, we treated rats with an escalating dose-multiple binge regimen, which we have suggested may more closely simulate human METH exposure profiles. Combined neuropathological and stereological analyses showed that 30 days after the last binge, there was shrinkage and degeneration in the pyramidal cell layers of the frontal cortex and in the hippocampal CA3 region. Further immunocytochemical analysis showed that METH exposure resulted in loss of calbindin interneurons in the neocortex and selective damage to pyramidal neurons in the CA3 region of the hippocampus and granular cells in the dentate gyrus that was accompanied by microglial activation. Taken together, these studies suggest that selective degeneration of pyramidal neurons and interneurons in the neocortex and limbic system might be involved in the cognitive alterations in METH users.     

Mu but not delta opioid receptor stimulation intensifies kainic acid-induced neurotoxicity in rat hippocampus

In the present study, we compared the effects of the selective mu agonist, [D-Ala2-N-methyl-pHe4-Gly-ol]-enkephalon (DAGO), and the selective delta agonist, [D-Pen2,5]-enkephalin (DPDPE), on kainic acid-induced neurotoxicity in rats. Infusion of kainic acid (0.5 ug/1.5 ul, ic.v.) alone caused pyramidal cell loss predominantly in hippocampal field CA3 with minimal involvement of the CA1 field. Coadministration of DAGO plus kainic acid into the lateral ventricle intensified the extent of degeneration of hippocampal pyramidal cells in the CA1 field. The potentiating effect of DAGO was completely blocked by naltrexone. In contrast, DPDPE had no significant effect on kainic acid-induced neurotoxicity. Thus, activation of mu but not delta receptors intensifies the neurotoxic effects of kainic acid in the hippocampus.     

Reduction of GABAB inhibitory postsynaptic potentials by serotonin via pre- and postsynaptic mechanisms in CA3 pyramidal cells of rat hippocampus in vitro.

The action of serotonin (5-HT) on GABAergic synaptic transmission was investigated with intracellular recordings in CA3 pyramidal cells of rat hippocampal slices. Local application of 5-HT (500 microM) hyperpolarized CA3 pyramidal cells, decreased cellular input resistance, and reduced slow afterhyperpolarizations. Serotonin attenuated the late (GABAB) component of polysynaptic inhibitory postsynaptic potentials (IPSPs; 47% of control) without affecting the early (GABAA) component. During bath application of the excitatory amino acid antagonists 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) (20 microM) and 2-amino-5-phosphonovalerate (AP-5) (40 microM), 5-HT similarly decreased the amplitude of the late (GABAB) component (17% of control) of monosynaptic IPSPs but did not affect the early (GABAA) component. The mean reversal potentials of poly- and monosynaptic IPSPs were unaffected by 5-HT. The conductance increases associated with the late component of poly- and monosynaptic IPSPs were reduced by 5-HT. Hyperpolarizing responses evoked in CA3 pyramidal cells by somatic applications of gamma-aminobutyric acid (GABA) were unaffected by 5-HT. During bath application of bicuculline (20-50 microM), hyperpolarizing responses elicited by dendritic GABA application were reduced by 5-HT (71% of control). The effect of 5-HT on these direct GABAB hyperpolarizations (29% decrease in response) does not appear sufficient to fully account for the effect of 5-HT on late GABAB IPSPs (53-83% decrease in response). Therefore, 5-HT may reduce GABAB IPSPs in CA3 pyramidal cells 1) by a postsynaptic action on pyramidal cells and 2) by a selective presynaptic action on GABAergic interneurons mediating the GABAB IPSP. This presynaptic action of 5-HT does not appear to involve excitatory afferents onto inhibitory interneurons.     

Stimulation-induced status epilepticus: role of the hippocampal mossy fibers in the seizures and associated neuropathology

A study of seizure activity and neuronal cell death produced by intracerebroventricular kainic acid had suggested that seizures conveyed by the hippocampal mossy fibers are more damaging to CA3 pyramidal cells than seizures conveyed by other pathways. To test this idea, the effects of a unilateral mossy fiber lesion were determined on seizure activity and neuronal degeneration provoked by repetitive electrical stimulation of the hippocampal fimbria in unanesthetized rats. Fimbrial stimulation resulted in self-sustained status epilepticus accompanied by neuronal degeneration in several brain regions, including area CA3 of the hippocampal formation. A unilateral mossy fiber lesion more readily attenuated the electrographic and behavioral seizures provoked by fimbrial stimulation than those provoked by kainic acid. If status epilepticus developed in the presence of a mossy fiber lesion, denervated CA3 pyramidal cells were still destroyed, although similar lesions protect these neurons from kainic acid-induced status epilepticus. Thus the two models of status epilepticus employ somewhat different seizure circuitries and neurodegenerative mechanisms. Seizures which involve the mossy fiber projection are not necessarily more damaging to CA3 pyramidal cells than seizures which do not.     

Inverse association of Pin1 and tau accumulation in Alzheimer's disease hippocampus

Neurofibrillary degeneration, one of the pathological hallmarks of Alzheimer's disease, is not ubiquitous to all brain regions or neurons. While a high degree of vulnerability has been documented for entorhinal cortex, hippocampal and neocortical pyramidal neurons other brain structures are largely spared. Even within highly vulnerable regions such as hippocampus neurons are affected to a variable extent. The molecular basis for this selective susceptibility remains unknown. Neurofibrillary degeneration involves hyperphosphorylation of tau which critically impairs its binding capacity to microtubule and, therefore, is believed to disrupt the axonal cytoskeleton. Recently, Lu et al. [Nature (1999) 399:784] described the ability of the peptidyl-prolyl cis-trans isomerase Pin1 to recover microtubule-binding affinity and microtubule stabilisation of phosphorylated tau. In the present study, we analysed the potential involvement of Pin1 in selective vulnerability of hippocampal neurons to neurofibrillary degeneration in Alzheimer's disease. Pin1 immunoreactivity appeared as cytoplasmic granules affecting hippocampal subfields to a different extent (CA2>subiculum>CA1>CA3/CA4). Since the main markers of granulovacuolar degeneration do not co-label Pin1-immunoreactive granules, we propose that these granules may represent a new lesion in Alzheimer's disease. Neurons containing Pin1 granules were devoid of neurofibrillary tangles. Granular accumulation of Pin1 may correspond to an absence of neurofibrillary lesions in these cells and might be associated with other mechanisms of neuronal degeneration.     

On the sites of presynaptic inhibition by neuropeptide y in rat hippocampus in vitro

Neuropeptide Y (NPY) reduces excitatory synaptic transmission between stratum radiatum and CA1 pyramidal cells in rat hippocampal slice in vitro by a presynaptic action. To understand NPY's role in the control of excitability in hippocampus, its actions on excitatory and inhibitory synaptic transmission were examined, using intracellular, sharp microelectrode, and tight-seal, whole cell recordings from principal neurons in areas CA1, CA3, and dentate. Bath application of 1 μM NPY reversibly inhibited excitatory postsynaptic potentials (EPSPs) evoked in CA1 pyramidal cells from either stratum radiatum or stratum oriens by about 50%. Neuropeptide Y also inhibited EPSPs at mossy fiber-CA3, stratum oriens-CA3, and CA3-CA3 synapses by between 45% and 55%. As in CA1, the action of NPY was presynaptic. By contrast, NPY did not inhibit EPSPs evoked in dentate granule cells from either perforant path or commissural inputs. Neuropeptide Y did not alter postsynaptic membrane properties in any cell type. Although NPY attenuated the orthodromically evoked (stratum radiatum) inhibitory postsynaptic potentials in CA1 pyramidal cells by about the same amount as it inhibited the EPSPs, it did not affect the IPSPs evoked in the same cells by antidromic stimulation from alveus. Inhibitory postsynaptic potentials evoked in pharmacological isolation in CA1, CA3, or dentate were also not significantly affected by NPY. The evidence supports the hypothesis that NPY acts at feedforward excitatory synapses to presynaptically reduce the amplitude of excitation as it travels through hippocampal circuits. By contrast, synaptically mediated inhibition is not directly affected by NPY. Neuropeptide Y is the only known endogenous substance that selectively reduces feedforward excitatory transmission without causing changes in other properties of the hippocampal circuitry.     

Mechanisms underlying the neuropathological consequences of epileptic activity in the rat hippocampus in vitro

Blockade of γ-aminobutyric acid (GABA)ergic synaptic transmission in mature hippocampal slice cultures for a period of 3 days with convulsants was shown previously to induce chronic epileptiform activity and to mimic many of the degenerative changes observed in the hippocampi of epileptic humans. The cellular mechanisms underlying the induction of this degeneration were examined in the present study by comparing the effects of GABA blockers with the effects produced by the K⁺ channel blocker tetraethylammonium (2 mM). Both types of convulsant caused a comparable decrease in the number of Nissl-stained pyramidal cells in areas CA1 and CA3. No significant cell loss was induced by tetraethylammonium when epileptiform discharge was reduced by simultaneous exposure of cultures to tetrodotoxin (0.5 μM) or to the anticonvulsants pentobarbital (50 μM) or tiagabine (50 μM). We conclude that this degeneration was mediated by convulsant-induced epileptiform discharge itself. The hypothesis that N-methyl-D-aspartate (NMDA) receptor-mediated excitotoxicity underlies cell death in this model was tested by applying convulsants together with specific antagonists of glutamate receptors. Whereas coapplication of antagonists of both non-NMDA and NMDA receptors strongly reduced the degeneration induced by the convulsants, application of either class of antagonist alone did not. Application of exogenous NMDA produced potent cell death, and this degeneration was blocked by the NMDA receptor antagonist methyl-10,11-dihydro-5-H-dibenzocyclohepten-5,10-imine (MK-801). Convulsants also induced a loss of dendritic spines that could be partially prevented by NMDA or non-NMDA receptor antagonists. We conclude that NMDA receptor activation is not solely responsible for the neuronal pathology resulting as a consequence of epileptiform discharge. © 1996 Wiley-Liss, Inc.     

Lesions of excitatory pathways reduce hippocampal cell death after transient forebrain ischemia in the gerbil

Summary Transient forebrain ischemia produces a spatially and temporally selective pattern of neuronal degeneration in the hippocampal formation of the Mongolian gerbil. Ischemic neuronal death has been suggested to depend on the activation of excitatory hippocampal pathways that project to the vulnerable neurons. This idea was tested by examining the effect of a unilateral entorhinal cortical lesion or a unilateral knife cut lesion of intrahippocampal pathways on the neuropathology produced by 5 min of complete fore-brain ischemia. A prior lesion of either the ipsilateral entorhinal cortex or the mossy fiber and Schaffer collateral-commissural pathways partially prevented the destruction of CA1b pyramidal cells in most animals. It did not, however, reduce the extent of ischemic neuronal death in any other hippocampal subfield. Within area CA1b, an entorhinal lesion protected an average of 23% of the pyramidal cells and a transection of both mossy and Schaffer collateral-commissural fibers protected an average of 36.5%. CA1b pyramidal cells saved from ischemia-induced degeneration appeared clearly abnormal when stained with cresyl violet or by silver impregnation. It is suggested that lesions of excitatory pathways attenuate ischemic damage to area CA1b by directly or indirectly reducing the level of synaptic excitation onto the vulnerable neurons. However, only a relatively small percentage of hippocampal neurons can be protected by these lesions in the gerbil ischemia model and there is reason to believe that the neurons protected in this manner may not be electrophysiologically competent. Synaptic excitation therefore appears to play an important, but not an essential, role in this model of ischemic brain damage.Supported by NIH Stroke Center grant NS 06233     

Modulation by substance P of synaptic transmission in the mouse hippocampal slice

The modulatory action of substance P on synaptic transmission of CA1 neurons was studied using intra‐ or extracellular recording from the mouse hippocampal slice preparation. Bath‐applied substance P (2–4 μ m ) or the selective NK₁ receptor agonist substance P methylester (SPME, 10 n m –5 μ m ) depressed field potentials (recorded from stratum pyramidale) evoked by focal stimulation of Schaffer collaterals. This effect was apparently mediated via NK₁ receptors since it was completely blocked by the selective NK₁ antagonist SR 140333. The field potential depression by SPME was significantly reduced in the presence of bicuculline. Intracellular recording from CA1 pyramidal neurons showed that evoked excitatory postsynaptic potentials (EPSPs) and evoked inhibitory postsynaptic potentials (IPSPs) were similarly depressed by SPME, which at the same time increased the frequency of spontaneous GABAergic events and reduced that of spontaneous glutamatergic events. The effects of SPME on spontaneous and evoked IPSPs were prevented by the ionotropic glutamate receptor blocker kynurenic acid. In tetrodotoxin (TTX) solution, no change in either the frequency of spontaneous GABAergic and glutamatergic events or in the amplitude of responses of pyramidal neurons to 4 μ m α‐amino‐3‐hydroxy‐5‐methyl‐4‐isoxazolepropionic acid (AMPA) or 10 μ m N ‐methyl‐ d ‐aspartate (NMDA) was observed. On the same cells, SPME produced minimal changes in passive membrane properties unable to account for the main effects on synaptic transmission. The present data indicate that SPME exerted its action on CA1 pyramidal neurons via a complex network mechanism, which is hypothesized to involve facilitation of a subset of GABAergic neurons with widely distributed connections to excitatory and inhibitory cells in the CA1 area.     

Selective spread of neurotropic herpesviruses in the rat hippocampus

Transsynaptically spreading viruses are widely used for tracing neuronal circuits in both the central and peripheral nervous systems. However, viruses are capricious tools with selective spreading properties that can produce false-negative results. Using herpes simplex virus type 1 and two pseudorabies virus strains, we aimed at mapping quantitatively neuronal connections in the rat hippocampus. We found that none of the tested viruses infected CA3 pyramidal neurons across synapses following inoculation into the CA1 area. Combined injections of the viruses with the retrograde tracer cholera toxin B (CTB) resulted in CTB, but not virus labeling of CA3 pyramidal neurons. In contrast, other brain regions known to send inputs to the CA1 (the entorhinal cortex, medial septum and diagonal band of Broca, raphe nuclei) were transsynaptically infected. Our results indicate that Schaffer collaterals of CA3 pyramidal cells lack the appropriate cellular machinery for successful neurotropic herpesvirus infection. After injections of viruses into the dentate gyrus/CA3 area, we found labeling in commissurally projecting mossy cells and their afferent granule cells but not in contralateral CA3 pyramidal cells. Using this unique spreading property, we estimated that single mossy cells receive input from a compact cluster of 30-40 granule cells.     

Exposure to excess glucocorticoids alters dendritic morphology of adult hippocampal pyramidal neurons.

We have used Golgi-impregnated tissue to demonstrate that exposure to excess glucocorticoids alters dendritic morphology in a specific population of neurons in the adult rat hippocampus. Daily injection of 10 mg of corticosterone for 21 days resulted in decreased numbers of apical dendritic branch points and decreased total apical dendritic length measured in a 100-microns-thick section in CA3 pyramidal cells compared to sham-injected and non-injected controls. In contrast, no changes were observed in CA3 pyramidal cell basal dendritic morphology. Furthermore, no changes were observed in the dendritic morphology of CA1 pyramidal cells or granule cells of the dentate gyrus. Cross-sectional cell body area of any of the 3 cell types examined in this study was unaffected by corticosterone treatment. Finally, qualitative analysis of Nissl-stained tissue from the same brains revealed increased numbers of darkly staining, apparently shrunken CA3 pyramidal cells in corticosterone treated compared to control brains. The changes in dendritic morphology we have observed may be indicative of neurons in the early stages of degeneration, as prolonged exposure to high levels of corticosterone has been shown by others to result in a loss of CA3 pyramidal cells. Additionally, these results suggest possible structural alterations which may occur under physiological conditions in which corticosterone levels are chronically elevated such as in aged animals.     

Reaction of astrocytes in the gerbil hippocampus following transient ischemia: immunohistochemical observations with antibodies against glial fibrillary acidic protein, glutamine synthetase, and S-100 protein.

An immunohistochemical method was used to study the distribution and changes with time of the astrocytic reaction in the gerbil hippocampus following transient ischemia. Three markers were investigated with specific antibodies to glial fibrillary acidic protein (GFAP), glutamine synthetase (GS), and S-100 protein. On Day 2 after ischemia, and more prominently on Day 3, reactive astrocytes were intensely stained for GFAP in the hippocampal formation, especially in the CA1 region and dentate gyrus. This response by astrocytes preceded CA1 pyramidal cell degeneration, which became apparent on Day 5. On Day 5, immunoreactive cells were not stained as intensely as on Day 3, but cells in the CA1 region and dentate gyrus were still more intensely stained than those in normal animals. GS and S-100 showed similar changes in distribution after ischemia, although the change in GS was less prominent: the hilus of the dentate gyrus was most intensely stained. Both immunoreactivities seemed to increase rather transiently on Day 2 or 3 and to decrease to the initial level on Day 5. The fact that reactive astrocytes appeared in CA1 before the onset of visible neural degeneration indicates that signals from indisposed neurons may be transmitted to astrocytes for their quick functioning. It is also suggested that degenerative changes occur in the dentate gyrus and may be involved in the delayed neural death of CA1 pyramidal cells. These observations indicate that astrocytes play a role in the neural degeneration induced by ischemia and that several types of astrocytes seem to react differently.     

Mapping second messenger systems in the rat hippocampus after transient forebrain ischemia: in vitro [3H]forskolin and [3H]inositol 1,4,5-trisphosphate binding

Autoradiographic imaging demonstrated predominant and reciprocal localization of forskolin and inositol 1,4,5-trisphosphate (IP3) binding sites in synaptic areas in the hippocampus. We produced selective damage to the CA1 pyramidal cells in the rat hippocampus by means of transient forebrain ischemia and analyzed the alteration of the intracellular signal transduction using quantitative autoradiography of these second messenger systems. The dendritic fields (stratum oriens, radiatum and lacunosummoleculare) in the CA1 showed 20% decrease in [3H]IP3 binding activity 3 h after ischemia, when no morphological abnormalities were obvious. Thereafter, grain density in these layers decreased and half of the binding sites were lost 2 days after ischemia. By contrast, the stratum pyramidale of the CA1 showed no significant change until 2 days after recirculation. Seven days after ischemia, when CA1 pyramidal cells were depleted, all layers in the CA1 subfield lost 85% of [3H]IP3 binding sites. In the CA3 subfield, only a small and transient alteration in the [3H]IP3 binding was noticed during recirculation. Postischemic reduction of [3H]forskolin binding sites was obvious in the CA1 only 1 h after ischemia followed by loss of 50% of binding activity 7 days after recirculation. These results suggest that forskolin and IP3 binding sites are predominantly distributed on the pyramidal cells in the CA1 subfield and that marked alteration of intracellular signal transduction precedes the delayed CA1 pyramidal cell death.