A chronic histopathological and electrophysiological analysis of a rodent hypoxic-ischemic brain injury model and its use as a model of epilepsy

Ischemic brain injury is one of the leading causes of epilepsy in the elderly, and there are currently no adult rodent models of global ischemia, unilateral hemispheric ischemia, or focal ischemia that report the occurrence of spontaneous motor seizures following ischemic brain injury. The rodent hypoxic-ischemic (H-I) model of brain injury in adult rats is a model of unilateral hemispheric ischemic injury. Recent studies have shown that an H-I injury in perinatal rats causes hippocampal mossy fiber sprouting and epilepsy. These experiments aimed to test the hypothesis that a unilateral H-I injury leading to severe neuronal loss in young-adult rats also causes mossy fiber sprouting and spontaneous motor seizures many months after the injury, and that the mossy fiber sprouting induced by the H-I injury forms new functional recurrent excitatory synapses. The right common carotid artery of 30-day old rats was permanently ligated, and the rats were placed into a chamber with 8% oxygen for 30 min. A quantitative stereologic analysis revealed that the ipsilateral hippocampus had significant hilar and CA1 pyramidal neuronal loss compared with the contralateral and sham-control hippocampi. The septal region from the ipsilateral and contralateral hippocampus had small but significantly increased amounts of Timm staining in the inner molecular layer compared with the sham-control hippocampi. Three of 20 lesioned animals (15%) were observed to have at least one spontaneous motor seizure 6-12 months after treatment. Approximately 50% of the ipsilateral and contralateral hippocampal slices displayed abnormal electrophysiological responses in the dentate gyrus, manifest as all-or-none bursts to hilar stimulation. This study suggests that H-I injury is associated with synaptic reorganization in the lesioned region of the hippocampus, and that new recurrent excitatory circuits can predispose the hippocampus to abnormal electrophysiological activity and spontaneous motor seizures.     

Seizures, cell death, and mossy fiber sprouting in kainic acid-treated organotypic hippocampal cultures

Sprouting of the mossy fiber axons of the dentate granule cells is a structural neuronal plasticity found in the mature brain of epileptic humans and experimental animals. Mossy fiber sprouting typically arises in experimental animals after repeated seizures and may contribute to the hyperexcitability of the epileptic brain. Investigation of the molecular triggers and spatial cues involved in mossy fiber sprouting has been hampered by the lack of an optimal in vitro model for studying this rearrangement. For an in vitro model to be feasible, the circuitry and receptors involved in convulsant-induced mossy fiber sprouting would have to be localized near the granule cells, rather than being dependent on long-range brain interconnections. However, it is not known whether this is the case. We report here that that application of the convulsant, kainic acid, to organotypic hippocampal explant cultures induces seizures, neuronal cell death, and subsequent dramatic mossy fiber sprouting with a similar laminar preference and time-course to that seen in intact animals. Prolonged (48 h) but not transient (4 h) kainic acid treatment caused regionally selective neuronal cell death. Cultures treated with kainic acid for a prolonged period displayed a time- and dose-dependent increase in supragranular Timm staining reflective of increased mossy fiber innervation to this area. Direct visualization of mossy fiber axons with neurobiotin-labeling revealed that mossy fibers in kainic acid-treated cultures exhibited a dramatic increase in supragranular axonal branch points and synaptic boutons. The cellular and molecular determinants required for kainic acid-induced cell death and subsequent mossy fiber reorganization thus appear to be intrinsic to the hippocampal slice preparation, and are preserved in culture. Given the ease with which functional inhibitors or pharmacological agents may be utilized in this system, slice cultures may provide a powerful model in which to study the molecular components involved in triggering mossy fiber outgrowth and underlying its laminar specificity. Elucidation of these molecular pathways will likely have both specific utility in clarifying the functional consequences of mossy fiber sprouting, as well as general utility in understanding of synaptic reorganization in the mature central nervous system.     

Hippocampal cell proliferation and epileptogenesis after audiogenic kindling are not accompanied by mossy fiber sprouting or Fluoro-Jade staining

Repetitive sound-induced seizures, known as audiogenic kindling (AK), gradually induce the transference of epileptic activity from brainstem to forebrain structures along with behavioral changes. The aim of our work was to correlate the behavioral changes observed during the AK with possible alterations in neuronal proliferation, cell death, hippocampal mossy fiber sprouting and in the EEG pattern of Wistar audiogenic rats, a genetically susceptible strain from our laboratory.Susceptible and non-susceptible animals were submitted to repeated sound stimulations for 14-16 days and hippocampal mitotic activity was studied through the incorporation of bromodeoxyuridine (BrdU). Cell death and mossy fiber sprouting were assessed, respectively, by using Fluoro-Jade and Timm staining, 2 and 32 days after the last kindling stimulation. In addition, we used immunofluorescent double labeling for a glial and a mitotic marker to evaluate newly born cell identity. Some animals had hippocampus and amygdala electrodes for EEG recordings.Our results show that kindled animals with 6-11 generalized limbic seizures (class IV-V) had increased cell proliferation in the dentate gyrus when compared with animals with zero or one to three seizures. BrdU-positive cells labeled on day 2 and on day 32 were both GFAP negative. In the later group, rounded and well-defined BrdU-positive/GFAP-negative nuclei were seen in different portions of the granule cell layer. We did not observe any Fluoro-Jade or differential Timm staining in kindled animals at both killing times. However, EEG recordings showed intense epileptic activity in the hippocampus and amygdala of all animals with limbic seizures.Therefore, our data indicate that AK-induced limbic epileptogenicity is able to increase the hippocampal mitotic rate, even though it does not seem to promote neuronal death or mossy fiber sprouting in the supragranular layer of the dentate gyrus.     

The development, ultrastructure and synaptic connections of the mossy cells of the dentate gyrus

Summary One of the most distinctive and common cell types in Golgi preparations of the hilus of the rat dentate gyrus is the mossy cell. We have used a variety of techniques including the Golgi method, the combined Golgi and electron microscopic (EM) method and the retrograde transport of horseradish peroxidase (HRP) to study the development, ultrastructure and synaptic connections of this cell type. The mossy cells identified in our light microscopic preparations are characterized by: (1) triangular or multipolar shaped somata; (2) three to four primary dendrites that arise from the soma and bifurcate once or more to produce an extensive dendritic arborization restricted, for the most part, to the hilus; (3) numerous thorny excrescences on their somata and proximal dendrites with typical spines on distal dendrites; and (4) axons that bifurcate and are directed toward the fimbria and the molecular layer of the dentate gyrus.The mossy cells have an immature appearance at birth and on subsequent days their maturation appears to lag somewhat behind that of the hippocampal pyramidal cells. On postnatal day 1, many of the dendrites bear growth cones primarily at their termini and have long, thin filipodia emanating from various points along their lengths. Many of the dendrites enter the molecular layer of the dentate gyrus, though this is rarely seen in the mature brain. Typical pedunculate spines are first commonly seen on the distal dendrites around postnatal day 7 while thorny excrescences are first commonly seen between postnatal days 11 and 14. By postnatal day 21, the dendrites have attained a mature appearance although the density of both typical spines and thorny excrescences is less than that found in adults.Two different retrograde transport methods were used to confirm that mossy cells give rise to the commissural projection to the contralateral dentate gyrus. The first method combined HRP histochemistry with a silver intensification procedure and the second method combined HRP histochemistry with Golgi staining. While the majority of commissurally projecting hilar neurons had the appearance of mossy cells, there were others that were smaller and either ovoid or fusiform.     

不同成熟期大鼠戊四氮反复惊厥模型与癫痫发病机制研究

目的：观察新生大鼠、成熟大鼠反复惊厥后海马结构的变化及NF-κB 表达，探索未成熟脑癫痫发病机制。 方法： 对生后10 d、60 d（P10、P60）两实验组大鼠用戊四氮(PTZ)反复腹腔注射5 d，设P10、P60生理盐水对照组；硫堇染色对CA1、CA3、DG及门区神经元进行细胞计数, 观察海马神经元坏死及凋亡；免疫组化技术检测NF-κB的表达；Timm组织化学染色观察苔藓纤维发芽并评分。 结果： (1) P10实验组与对照组比较，海马齿状回、CA1、CA3区无明显神经元丢失，DG区颗粒细胞数在实验组(23.25±3.06) 多于对照组（16.25±1.58）；P60实验组CA1、CA3区神经元计数（8.22±1.88、5.62±1.68）明显少于对照组（6.31±1.50、3.62±1.40），DG区无明显差异；（2）两实验组CA3区锥体层苔藓纤维发芽均多于对照组，但P60(3.25±1.03)较P10（1.50±0.92）更明显；（3）P10、P60实验组NF-κB 表达高于对照组，且P10组较P60组更为明显（P<0.05）。 结论： 新生大鼠致痫后海马神经元无明显丢失，脑内NF-κB 表达增加，可能是未成熟脑对惊厥性脑损伤具有耐受性的重要神经生物学基础。     

Activity-dependent changes in synaptophysin immunoreactivity in hippocampus,piriform cortex,and entorhinal cortex of the rat

Synaptophysin, an integral membrane glycoprotein of synaptic vesicles, has been widely used to investigate synaptogenesis in both animal models and human patients. Kindling is an experimental model of complex partial seizures with secondary generalization, and a useful model for studying activation-induced neural growth in adult systems. Many studies using Timm staining have shown that kindling promotes sprouting in the mossy fiber pathway of the dentate gyrus. In the present study, we used synaptophysin immunohistochemistry to demonstrate activation-induced neural sprouting in non-mossy fiber cortical pathways in the adult rat. We found a significant kindling-induced increase in synaptophysin immunoreactivity in the stratum radiatum of CA1 and stratum lucidum/radiatum of CA3, the hilus, the inner molecular layer of the dentate gyrus, and layer II/III of the piriform cortex, but no significant change in layer II/III of the entorhinal cortex, 4 weeks after the last kindling stimulation. We also found that synaptophysin immunoreactivity was lowest in CA3 near the hilus and increased with increasing distance from the hilus, a reverse pattern to that seen with Timm stains in stratum oriens following kindling. Furthermore, synaptophysin immunoreactivity was lowest in dorsal and greatest in ventral sections of both CA3 and dentate gyrus in both kindled and non-kindled animals. This demonstrates that different populations of sprouting axons are labeled by these two techniques, and suggests that activation-induced sprouting extends well beyond the hippocampal mossy fiber system.     

Post-ischemic synaptic plasticity in the rat hippocampus after long-term survival: histochemical and autoradiographic study.

The hippocampus provides a suitable area in the brain for the analysis of neuronal plasticity after application of a selective lesioning technique. Using histochemistry and autoradiography, we studied synaptic reorganization in the rat hippocampus with selective CA1 pyramidal cell lesioning caused by transient forebrain ischemia after long-term survival. An autoradiographic study was performed on second messenger systems ([3H]inositol 1,4,5-trisphosphate, [3H]forskolin and [3H]phorbol 12,13-dibutyrate binding). One-hundred days after ischemia, depletion of CA1 pyramidal cells and marked shrinkage of the CA1 subfield was noted in spite of unaltered thickness of the CA3 band and of the dentate molecular layers. Although neuronal density in the CA3 region of animals killed seven days after ischemia was not different from the normal group, 78% of animals showed neuronal loss of 30-50% in the stratum pyramidale of the CA3b 100 days after recirculation. Sixty-seven per cent of animals exhibited supragranular mossy fiber sprouting in the dentate gyrus. However, CA3 neuronal loss did not correlate with mossy fiber sprouting. Succinic dehydrogenase was depleted in the CA1 100 days after ischemia, and animals with CA3 damage showed a reduction of succinic dehydrogenase activity in the CA3. In contrast to the unaltered acetylcholinesterase in the animals killed seven days after ischemia, high density bands of acetylcholinesterase activity in the stratum pyramidale of the CA1 were found to be broadened 100 days after ischemia. In the CA1 subfield, subnormal activity of [3H]phorbol 12,13-dibutyrate and [3H]forskolin binding were observed in spite of the depleted [3H]inositol 1,4,5-triphosphate binding. [3H]Forskolin binding in the hilus had increased by 62% 100 days after ischemia, although binding in the stratum lucidum of the CA3 and in the stratum moleculare of the dentate gyrus was unaltered. However, no visible supragranular increase in [3H]forskolin binding was observed. These results indicate that long-term survival after CA1 pyramidal cell depletion caused by transient forebrain ischemia induced the modulation of neuronal activity and synaptic rearrangements in the whole hippocampal formation.     

Reassessment of the effects of cycloheximide on mossy fiber sprouting and epileptogenesis in the pilocarpine model of temporal lobe epilepsy

A feature of animal models of temporal lobe epilepsy and the human disorder is hippocampal sclerosis and Timm stain in the inner molecular layer (IML) of the dentate gyrus, which represents synaptic reorganization and may be important in epileptogenesis. We reassessed the hypothesis that pre-treatment with cycloheximide (CHX) prevents Timm staining in the IML following pilocarpine (PILO)-induced status epilepticus (a multifocal model of temporal lobe epilepsy), but allows epileptogenesis (i.e., chronic spontaneous seizures) after a latent period. Hippocampal slices from PILO-treated rats without Timm stain in the IML after CHX treatment were hypothesized to lack the electrophysiological abnormalities suggestive of recurrent excitation. The primary experimental groups were as follows: 1) CHX (1 mg/kg) 30-45 min prior to administration of PILO (320 mg/kg ip, 2) only PILO, and 3) only saline (0.5 ml, IP). The CHX pre-treatment significantly decreased the number of rats that responded to PILO with status epilepticus compared to rats that received only PILO. Pre-treatment with CHX did not significantly alter the spontaneous motor seizure rate post-treatment compared to treatment with PILO alone in those animals from each group that developed status epilepticus during PILO treatment. Timm stain in the IML was not significantly different between the PILO- and PILO+CHX-treated rats. Using quantitative methods, CHX did not prevent hilar, CA1, or CA3 neuronal loss compared to the PILO-treated rats. Extracellular responses to hilar stimulation in 30 microM bicuculline and 6 mM [K(+)](o) demonstrated all-or-none bursting in both the CHX+PILO- and PILO-treated rats but not in control rats. Whole cell recordings from granule cells, using glutamate flash photolysis to activate other granule cells, showed that both the CHX+PILO- and PILO-treated rats had excitatory synaptic interactions in the granule cell layer, which were not found after saline treatment. Some rats responded to PILO (with or without CHX pre-treatment) with only one or a few seizures at treatment, and some of these animals (n = 4) demonstrated spontaneous motor seizures within 2 mo after treatment. Timm staining and neuron loss in this group were not clearly different from saline-treated rats. These results suggest that in the PILO model, pre-treatment with CHX does not affect mossy fiber sprouting in the IML of epileptic rats and does not prevent the formation of recurrent excitatory circuits. However, the develoment of spontaneous motor seizures, in a small number of rats, could occur without detectable hippocampal neuron loss or mossy fiber sprouting, as assessed by the Timm stain method.     

Involvement of highly polysialylated neural cell adhesion molecule (PSA-NCAM)-positive granule cells in the amygdaloid-kindling-induced sprouting of a hippocampal mossy fiber trajectory

The mossy fiber system in the hippocampus of amygdaloid-kindled rats was examined by using highly polysialylated neural cell adhesion molecule (PSA-NCAM) as a marker for immunohistochemical detection of immature dentate granule cells and mossy fibers in combination with bromodeoxyuridine (BrdU) labeling of newly generated granule cells. Statistically significant increases in BrdU-labeled cells and PSA-NCAM-positive cells occurred in the dentate gyrus following kindling. The increase in PSA-NCAM-immunoreactive neurites was confined to the entire stratum lucidum of CA3. Immunoelectron-microscopic examination also revealed that PSA-NCAM-positive immature synaptic terminals of the sprouting mossy fibers increased in the stratum lucidum of CA3 in the kindled rats. The increase in the numbers of PSA-NCAM-positive granule cells correlated well with the increase in the immunopositive neurites and synaptic terminals on the mossy fiber trajectory. The increase in these PSA-NCAM-immunopositive structures is thought to reflect the enhancement of sprouting and synaptogenesis of mossy fibers by a subset of granule cells newly generated during amygdaloid-kindling and suggests that the reorganization of the mossy fiber system on the normal trajectory at least in part contributes to the acquisition and maintenance of an epileptogenic state.     

Lesion-induced transneuronal plasticity in the adult rat hippocampus

The process of reactive synaptogenesis has been demonstrated in several areas of the central nervous system, including the hippocampal dentate gyrus. After a complete unilateral entorhinal lesion, approximately 85% of the input to the outer two-thirds of the ipsilateral dentate molecular layer is lost. Bilateral fluctuations in synaptic density within non-denervated zones of the dentate molecular layer predict further alterations in neural circuitry at sites located transneuronally to the denervated dentate granule cells. Using quantitative electron microscopy, our study demonstrates a complete cycle of synapse loss and reacquisition within the ipsilateral but not contralateral CA4/hilus region of the hippocampal formation. This area is one of the terminal fields for the dentate granule cell mossy fiber axons. In addition the granule cell mossy fiber axons sprout during the postlesion time course and form a significantly increased number of new mossy fiber terminals within the ipsilateral and contralateral CA4/hilus area. Our results indicate that responses to brain injury may no longer be confined to a local denervated site, but probably include polyneuronal circuitry loops, which may encompass one or more areas of the central nervous system. Previous difficulties in providing a close behavioral or functional correlation to localized structural events may be explained by a more global brain response to an injury.     

Expression of synaptopodin, an actin-associated protein, in the rat hippocampus after limbic epilepsy

Synaptopodin, a 100 kD protein, associated with the actin cytoskeleton of the postsynaptic density and dendritic spines, is thought to play a role in modulating actin-based shape and motility of dendritic spines during formation or elimination of synaptic contacts. Temporal lobe epilepsy in humans and in rats shows neuronal damage, aberrant sprouting of hippocampal mossy fibers and subsequent synaptic remodeling processes. Using kainic acid (KA) induced epilepsy in rats, the postictal hippocampal expression of synaptopodin was analyzed by in situ hybridization (ISH) and immunohistochemistry. Sprouting of mossy fibers was visualized by a modified Timm's staining. ISH showed elevated levels of Synaptopodin mRNA in perikarya of CA3 principal neurons, dentate granule cells and in surviving hilar neurons these levels persisted up to 8 weeks after seizure induction. Synaptopodin immunoreactivity in the dendritic layers of CA3, in the hilus and in the inner molecular layer of the dentate gyrus (DG) was initially reduced. Eight weeks after KA treatment Synaptopodin protein expression returned to control levels in dendritic layers of CA3 and in the entire molecular layer of the DG. The recovery of protein expression was accompanied by simultaneous supra- and infragranular mossy fiber sprouting. Postictal upregulation of Synaptopodin mRNA levels in target cell populations of limbic epilepsy-elicited damage and subsequent Synaptopodin protein expression largely co-localized with remodeling processes as demonstrated by mossy fiber sprouting. It may thus represent a novel postsynaptic molecular correlate of hippocampal neuroplasticity.     

Non-competitive antagonists of NMDA and AMPA receptors decrease seizure-induced c-fos protein expression in the cerebellum and protect against seizure symptoms in adult rats

The aim of the present study was to examine the role of ionotropic glutamate receptors in the cerebellum during generalized seizures. Epileptic neuronal activation was evaluated through the immunohistochemical detection of c-fos protein in the cerebellar cortex. Generalized seizures were precipitated by the intraperitoneal injection of 4-aminopyridine. The animals were pretreated with the NMDA receptor antagonists MK-801 (2?mg/kg), amantadine (50?mg/kg), and the AMPA receptor antagonist GYKI 52466 hydrochloride (50?mg/kg). Two hours after 4-aminopyridine injection, the number of c-fos immunostained cell nuclei was counted in serial immunohistochemical sections of the cerebellar vermis. The number of c-fos immunostained cell nuclei in the granular layer decreased significantly in animals pretreated with the glutamate receptor antagonists compared to the untreated animals having convulsion. We can conclude that mossy fiber stimulation exerts its seizure-generating action mainly through the ionotropic glutamate receptors of the mossy fiber synapses. Both NMDA and AMPA receptor antagonists are effective in reducing glutamate-mediated postsynaptic effects in the cerebellar cortex.     

Hippocampal neurons and glia in epileptic EL mice

Reactive changes in hippocampal astrocytes are frequently encountered in association with temporal lobe epilepsy in humans and with drug or kindling-induced seizures in animal models. These reactive changes generally involve increases in astrocyte size and number and often occur together with neuronal loss and synaptic rearrangements. In addition to producing astrocytic changes, seizure activity can also produce reactive changes in microglia, the resident macrophages of brain. In this study, we examined the effects of recurrent seizure activity on hippocampal neurons and glia in the epileptic EL mouse, a natural model of human multifactorial idiopathic epilepsy and complex partial seizures. Timm staining was used to evaluate infrapyramidal mossy fiber organization and the optical dissector method was used to count Nissl-stained neurons in hippocampus of adult (about one year of age) EL mice and nonepileptic C57BL/6J (B6) and DDY mice. Immunostaining forglial fibrillary acidic protein (GFAP) and Iba1, an actin cross-linking molecule restricted to macrophages and microglia, was used to evaluate astrocytes and microglia, respectively. The EL mice experienced about 25–30 complex partial seizures with secondary generalization during routine weekly cage changing. No significant differences were found among the mouse strains for Timm staining scores or for neuronal counts in the CA1 and CA3 pyramidal fields or in the hilus. However, the number of GFAP-positive astrocytes was significantly elevated in the stratum radiatum and hilus of EL mice, while microglia appeared hyper-ramified and were more intensely stained in EL mice than in the B6 or DDY mice in the hilus, parietal cortex, and pyriform cortex. The results indicate that recurrent seizure activity in EL mice is associated with abnormalities in hippocampal astrocytes and brain microglia, but is not associated with obvious neuronal loss or mossy fiber synaptic rearrangements. The EL mouse can be a useful model for evaluating neuron-glia interactions related to idiopathic epilepsy.     

Recurrent excitatory connectivity in the dentate gyrus of kindled and kainic acid-treated rats

Repeated seizures induce mossy fiber axon sprouting, which reorganizes synaptic connectivity in the dentate gyrus. To examine the possibility that sprouted mossy fiber axons may form recurrent excitatory circuits, connectivity between granule cells in the dentate gyrus was examined in transverse hippocampal slices from normal rats and epileptic rats that experienced seizures induced by kindling and kainic acid. The experiments were designed to functionally assess seizure-induced development of recurrent circuitry by exploiting information available about the time course of seizure-induced synaptic reorganization in the kindling model and detailed anatomic characterization of sprouted fibers in the kainic acid model. When recurrent inhibitory circuits were blocked by the GABA(A) receptor antagonist bicuculline, focal application of glutamate microdrops at locations in the granule cell layer remote from the recorded granule cell evoked trains of excitatory postsynaptic potentials (EPSPs) and population burst discharges in epileptic rats, which were never observed in slices from normal rats. The EPSPs and burst discharges were blocked by bath application of 1 microM tetrodotoxin and were therefore dependent on network-driven synaptic events. Excitatory connections were detected between blades of the dentate gyrus in hippocampal slices from rats that experienced kainic acid-induced status epilepticus. Trains of EPSPs and burst discharges were also evoked in granule cells from kindled rats obtained after > or = 1 wk of kindled seizures, but were not evoked in slices examined 24 h after a single afterdischarge, before the development of sprouting. Excitatory connectivity between blades of the dentate gyrus was also assessed in slices deafferented by transection of the perforant path, and bathed in artificial cerebrospinal fluid (ACSF) containing bicuculline to block GABA(A) receptor-dependent recurrent inhibitory circuits and 10 mM [Ca(2+)](o) to suppress polysynaptic activity. Low-intensity electrical stimulation of the infrapyramidal blade under these conditions failed to evoke a response in suprapyramidal granule cells from normal rats (n = 15), but in slices from epileptic rats evoked an EPSP at a short latency (2.59 +/- 0.36 ms) in 5 of 18 suprapyramidal granule cells. The results are consistent with formation of monosynaptic excitatory connections between blades of the dentate gyrus. Recurrent excitatory circuits developed in the dentate gyrus of epileptic rats in a time course that corresponded to the development of mossy fiber sprouting and demonstrated patterns of functional connectivity corresponding to anatomic features of the sprouted mossy fiber pathway.     

Optical recording study of granule cell activities in the hippocampal dentate gyrus of kainate-treated rats

In the epileptic hippocampus, newly sprouted mossy fibers are considered to form recurrent excitatory connections to granule cells in the dentate gyrus and thereby increase seizure susceptibility. To study the effects of mossy fiber sprouting on neural activity in individual lamellae of the dentate gyrus, we used high-speed optical recording to record signals from voltage-sensitive dye in hippocampal slices prepared from kainate-treated epileptic rats (KA rats). In 14 of 24 slices from KA rats, hilar stimulation evoked a large depolarization in almost the entire molecular layer in which granule cell apical dendrites are located. The signals were identified as postsynaptic responses because of their dependence on extracellular Ca(2+). The depolarization amplitude was largest in the inner molecular layer (the target area of sprouted mossy fibers) and declined with increasing distance from the granule cell layer. In the inner molecular layer, a good correlation was obtained between depolarization size and the density of mossy fiber terminals detected by Timm staining methods. Blockade of GABAergic inhibition by bicuculline enlarged the depolarization in granule cell dendrites. Our data indicate that mossy fiber sprouting results in a large and prolonged synaptic depolarization in an extensive dendritic area and that the enhanced GABAergic inhibition partly masks the synaptic depolarization. However, despite the large dendritic excitation induced by the sprouted mossy fibers, seizure-like activity of granule cells was never observed, even when GABAergic inhibition was blocked. Therefore, mossy fiber sprouting may not play a critical role in epileptogenesis.     

Autoradiographic analysis of [H]ryanodine binding sites in rat brain: Regional distribution and the effects of lesions on sites in the hippocampus

Quantitative and qualitative autoradiographic methods together with lesion approaches were used to determine the distribution of [3H]ryanodine binding sites in rat brain and the neuronal localization of these sites in the hippocampus. In normal animals, levels of [3H]ryanodine binding sites ranged from a low of about 1 fmol/mg tissue in subcortical structures to a high of 12-18 fmol/mg tissue in subregions of the hippocampus and the olfactory bulb. Relatively high densities of sites (5-9 fmol/mg tissue) were also seen in the olfactory tubercle, most areas of the cerebral cortex, accumbens nucleus, striatum, lateral septal nuclei, pontine nucleus, superior colliculus and granule cell layer of the cerebellum. Specific binding was undetectable in white matter. In experimental animals, intracerebral injections of kainic acid caused neuronal degeneration and a near total depletion of [3H]ryanodine binding sites in the dentate gyrus and in fields CA1, CA2 and CA3 of the hippocampus. Injections of kainic acid that left dentate granule cells largely intact while destroying all neurons in field CA3 had no effect on binding sites in the dentate gyrus. However, these lesions substantially reduced the density of binding in field CA3, leaving a narrow band of sites outlining the position of the degenerated CA3 pyramidal cells. Mechanical knife-cut lesions that severed the granule cell mossy fiber input to field CA3 reduced the density of binding sites in the CA3 region. The results indicate that [3H]ryanodine binding sites in brain are heterogeneously distributed and suggest that a proportion of these sites in the hippocampus may be contained in mossy fiber terminals where a presumptive calcium channel/ryanodine receptor complex may be involved in the regulation of calcium mobilization and/or neurotransmitter release.     

Recurrent mossy fiber pathway in rat dentate gyrus: synaptic currents evoked in presence and absence of seizure-induced growth

A common feature of temporal lobe epilepsy and of animal models of epilepsy is the growth of hippocampal mossy fibers into the dentate molecular layer, where at least some of them innervate granule cells. Because the mossy fibers are axons of granule cells, the recurrent mossy fiber pathway provides monosynaptic excitatory feedback to these neurons that could facilitate seizure discharge. We used the pilocarpine model of temporal lobe epilepsy to study the synaptic responses evoked by activating this pathway. Whole cell patch-clamp recording demonstrated that antidromic stimulation of the mossy fibers evoked an excitatory postsynaptic current (EPSC) in approximately 74% of granule cells from rats that had survived >10 wk after pilocarpine-induced status epilepticus. Recurrent mossy fiber growth was demonstrated with the Timm stain in all instances. In contrast, antidromic stimulation of the mossy fibers evoked an EPSC in only 5% of granule cells studied 4-6 days after status epilepticus, before recurrent mossy fiber growth became detectable. Notably, antidromic mossy fiber stimulation also evoked an EPSC in many granule cells from control rats. Clusters of mossy fiber-like Timm staining normally were present in the inner third of the dentate molecular layer at the level of the hippocampal formation from which slices were prepared, and several considerations suggested that the recorded EPSCs depended mainly on activation of recurrent mossy fibers rather than associational fibers. In both status epilepticus and control groups, the antidromically evoked EPSC was glutamatergic and involved the activation of both AMPA/kainate and N-methyl-D-aspartate (NMDA) receptors. EPSCs recorded in granule cells from rats with recurrent mossy fiber growth differed in three respects from those recorded in control granule cells: they were much more frequently evoked, a number of them were unusually large, and the NMDA component of the response was generally much more prominent. In contrast to the antidromically evoked EPSC, the EPSC evoked by stimulation of the perforant path appeared to be unaffected by a prior episode of status epilepticus. These results support the hypothesis that recurrent mossy fiber growth and synapse formation increases the excitatory drive to dentate granule cells and thus facilitates repetitive synchronous discharge. Activation of NMDA receptors in the recurrent pathway may contribute to seizure propagation under depolarizing conditions. Mossy fiber-granule cell synapses also are present in normal rats, where they may contribute to repetitive granule cell discharge in regions of the dentate gyrus where their numbers are significant.     

Continuous infusion of neurotrophin-3 triggers sprouting,decreases the levels of TrkA and TrkC,and inhibits epileptogenesis and activity-dependent axonal growth in adult rats

Neurotrophin-3 (NT-3), a member of the neurotrophin family of neurotrophic factors, is important for cell survival, axonal growth and neuronal plasticity. Epileptiform activation can regulate the expression of neurotrophins, and increases or decreases in neurotrophins can affect both epileptogenesis and seizure-related axonal growth. Interestingly, the expression of nerve growth factor and brain-derived neurotrophic factor is rapidly up-regulated following seizures, while NT-3 mRNA remains unchanged or undergoes a delayed down-regulation, suggesting that NT-3 might have a different function in epileptogenesis. In the present study, we demonstrate that continuous intraventricular infusion of NT-3 in the absence of kindling triggers mossy fiber sprouting in the inner molecular layer of the dentate gyrus and the stratum oriens of the CA3 region. Furthermore, despite this NT-3-related sprouting effect, continuous infusion of NT-3 retards the development of behavioral seizures and inhibits kindling-induced mossy fiber sprouting in the inner molecular layer of the dentate gyrus. We also show that prolonged infusion of NT-3 leads to a decrease in kindling-induced Trk phosphorylation and a down-regulation of the high-affinity Trk receptors, TrkA and TrkC, suggesting an involvement of both cholinergic nerve growth factor receptors and hippocampal NT-3 receptors in these effects. Our results demonstrate an important inhibitory role for NT-3 in seizure development and seizure-related synaptic reorganization.     

5'-Nucleotidase activity of mossy fibers in the dentate gyrus of normal and epileptic rats.

Sprouting of mossy fibers in the hippocampus of rats that underwent limbic epileptogenesis by amygdala kindling or kainate injection was studied at the light microscopic and ultrastructural levels by cytochemical demonstration of the enzyme 5'-nucleotidase. This adenosine-producing ectoenzyme has previously been shown to characterize malleable terminals during brain development and lesion-induced synaptogenesis, but to be otherwise associated with glial membranes. At the light microscopic level, kainate-treated but not control or kindled rats showed 5'-nucleotidase activity in the CA3 region and in the inner molecular layer of the dentate gyrus. At the ultrastructural level, in control animals, the synapses of the molecular and granular layers were enzyme negative. Only some mossy fiber boutons of the dentate hilus exhibited 5'-nucleotidase activity. In epileptic rats, synaptic labeling within the hilus appeared more intense. Moreover, 5'-nucleotidase-containing terminals within the inner molecular layer, presumably ectopic mossy fiber boutons, were found in both kindled and kainate-treated rats. It is concluded that, in both the normal and epileptic hippocampus, 5'-nucleotidase is associated with axons capable of a plastic sprouting response. The synaptic enzyme may attenuate the glutamatergic transmission of mossy fibers, in particular of the aberrant mossy fibers in epileptic rats, by producing the inhibitory neuromodulator adenosine. Alternatively, 5'-nucleotidase may influence synapse formation by its putative non-enzymatic, adhesive functions.     

Excitatory synaptic input to granule cells increases with time after kainate treatment

Temporal lobe epilepsy is usually associated with a latent period and an increased seizure frequency following a precipitating insult. After kainate treatment, the mossy fibers of the dentate gyrus are hypothesized to form recurrent excitatory circuits between granule cells, thus leading to a progressive increase in the excitatory input to granule cells. Three groups of animals were studied as a function of time after kainate treatment: 1-2 wk, 2-4 wk, and 10-51 wk. All the animals studied 10-51 wk after kainate treatment were observed to have repetitive spontaneous seizures. Whole cell patch-clamp recordings in hippocampal slices showed that the amplitude and frequency of spontaneous excitatory postsynaptic currents (EPSCs) in granule cells increased with time after kainate treatment. This increased excitatory synaptic input was correlated with the intensity of the Timm stain in the inner molecular layer (IML). Flash photolysis of caged glutamate applied in the granule cell layer evoked repetitive EPSCs in 10, 32, and 66% of the granule cells at the different times after kainate treatment. When inhibition was reduced with bicuculline, photostimulation of the granule cell layer evoked epileptiform bursts of action potentials only in granule cells from rats 10-51 wk after kainate treatment. These data support the hypothesis that kainate-induced mossy fiber sprouting in the IML results in the progressive formation of aberrant excitatory connections between granule cells. They also suggest that the probability of occurrence of electrographic seizures in the dentate gyrus increases with time after kainate treatment.