Increased Expression of GAP-43, Somatostatin and Neuropeptide Y mRNA in the Hippocampus During Development of Hippocampal Kindling in Rats

The expression and distribution of the mRNA coding for the growth-associated protein-43 (GAP-43), a putative marker for neuritic growth, for preprosomatostatin and the preproneuropeptide Y (ppNPY) were analysed in the rat hippocampus during the development of hippocampal kindling by an in situ hybridization technique and computer-assisted grain counting in the cell. The levels of GAP-43 mRNA increased significantly in the CA3 pyramidal neurons and hilar polymorphic neurons of the dentate gyrus 2 days after stage 2 of kindling (preconvulsive stage) but not stage 5 (full seizure expression) in the stimulated hippocampus. The distribution of GAP-43 mRNA was the same in the hippocampus of kindled rats as in sham-stimulated animals. Preprosomatostatin mRNA and ppNPY mRNA contents rose significantly in the hilar polymorphic neurons of the dentate gyrus of the stimulated and contralateral hippocampus at both stages of kindling, with the greatest effect at stage 5. In addition, the number of ppNPY mRNA neurons in the fascia dentata was significantly higher in kindled rats than in controls, but there were no differences in the number of preprosomatostatin mRNA-positive cells. Preprosomatostatin and ppNPY mRNAs were also increased in the neurons of the stratum oriens of the CA1 - CA3 subfield of fully kindled animals, whereas at stage 2 only neurons of the CA1 stratum oriens showed a significant increase of preprosomatostatin mRNA. No changes in preprosomatostatin and ppNPY mRNA expression were observed in the various regions of the hippocampus after a single afterdischarge or 1 month after stage 5. These data show that synthesis of somatostatin and neuropeptide Y increases in certain neurons of the hippocampus during the development of hippocampal kindling, and support the suggestion that these peptides are involved in epileptogenesis. Moreover, the increased synthesis of GAP-43 may contribute to the synaptic remodelling of certain hippocampal neurons during kindling.     

Kindling: secondary epileptogenesis, sleep and catecholamines.

Seizure development and transference phenomenon were investigated in hippocampal and amygdaloid kindled cats. The behavioral and electrographic findings during the kindling procedures showed that motor seizure development in hippocampal seizures occurred with the emergence of independent discharging in the amygdala, globus pallidus and contralateral hippocampus. Furthermore, secondary site convulsions developed upon the first stimulation of these structures in the hippocampal group but only after over a month of hippocampal stimulation in the amygdaloid group. It was, therefore, concluded that role of the amygdala and globus pallidus in hippocampal seizure development was more essential than that of hippocampal stimulation in amygdaloid seiqure development. The common findings between the hippocampal and amygdaloid kindled animals were the systematic progression to seizures, the all-or-nothing nature of the electrical response and the relative permanency of the seizure susceptibility. Seizure susceptibility increased during slow wave sleep and decreased during REM sleep. These latter findings were examined with preliminary data of brain bioassays of catecholamines.     

Positive transfer of audiogenic kindling to electrical hippocampal kindling in rats.

Audiogenic seizures in genetically susceptible rodents are provoked by intense acoustic stimulations which result in a tonic seizure associated with a short flattening of the EEG. These seizures have been shown to involve primarily brainstem structures. Daily exposure to sound for 30-40 days produced a permanent change in the evoked seizure with development of facial myoclonias, rearing and falling, or of tonic-clonic seizures accompanied by high amplitude cortical spike-and-wave discharges. Kindled audiogenic seizures appear similar to seizures kindled from amygdala or hippocampus, suggesting that repeated auditory stimulations cause a progressive propagation of the epileptic discharge toward limbic structures. To verify this hypothesis, the behavioral and EEG development of electrical hippocampal kindling has been studied in 7 non epileptic controls (NE), 8 acoustic susceptible (AS), and 8 audiogenic kindled rats (KAS). The behavioral and EEG development of the electrical hippocampal kindling was similar in the AS and the NE rats. However, 2 animals in the AS group but no controls exhibited behavioral running and bouncing during the course of hippocampal kindling. In the KAS group, the hippocampal kindling was clearly facilitated as compared to NE and AS: behavioral stage greater than or equal to 5 was reached in a mean of 4 stimulations in KAS versus 30 and 22 stimulations respectively in NE and AS groups. This positive transfer phenomenon suggests that during kindling of audiogenic seizures, epileptic discharge spreads from the brainstem to the forebrain and progressively involves the hippocampus.     

大鼠杏仁核电刺激癫痫模型海马JNK的磷酸化改变

目的 研究大鼠杏仁核电点燃癫痫模型海马中JNK的磷酸化改变,探讨JNK磷酸化与癫痫发生发展的关系.方法 建立大鼠杏仁核电点燃癫痫模型.设立空白对照组、手术对照组、点燃组,癫痫点燃成功后取脑,分别采用Western blot和免疫荧光方法 检测海马中JNK的表达变化,采用TUNEL染色和GFAP免疫组化染色观察海马形态学改变.结果 36只大鼠在12-20 d成功点燃.Western blot显示点燃组磷酸化JNK水平较手术对照组和空白对照组高(P<0.05).形态学检测显示点燃组海马区神经元缺失及神经胶质细胞增生(P<0.05).结论 电刺激诱发大鼠癫痫发作后,海马组织JNK磷酸化水平升高,该信号通路的激活可能参与颞叶内侧癫痫海马硬化的发生过程.     

Electrically evoked GABA release in rat hippocampus CA1 region and its changes during kindling epileptogenesis

Previous findings on changes in K+-induced GABA release from hippocampal slices during kindling epileptogenesis were reinvestigated using physiological electrical stimulation. For that purpose, a procedure was developed enabling neurochemical monitoring of GABA release locally in the CA1 region of rat hippocampal slices upon tetanic stimulation of Schaffer-collateral fibers. In the presence of a GABA reuptake blocker, subsequent application of short (3 s) pulses of 50-Hz stimuli induced a local transient increase in GABA release. In slices from fully kindled animals, 24 h after the last generalized seizure, tetanically stimulated GABA release was increased in comparison to control slices. In slices from long-term kindled animals, 4-5 weeks after the last seizure, tetanically stimulated GABA release had returned to control levels. Application of the broad low-affinity GABAB receptor antagonist saclofen increased the tetanically stimulated GABA release in control slices, but had no effect in fully kindled slices. In slices from long-term kindled animals, however, saclofen enhanced GABA release similarly as in control slices. We conclude that the transient increase in tetanus-induced GABA release during kindling epileptogenesis is seizure-related, and probably caused by temporarily impaired presynaptic GABAB receptors. The possible relevance of this finding for GABA transmission in epilepsy is discussed.     

Evidence for long-term reduction of noradrenaline release after kindling in the rat hippocampus

The in vivo microdialysis technique was used to monitor steady-state noradrenaline release in the rat hippocampus after hippocampal kindling. At 8 weeks after the last seizure, the noradrenaline release was reduced by 62% in the stimulated hippocampus in kindled animals as compared to non-kindled rats. The reduction was not due to the repeated handling of the animals as assessed in a separate experiment. The results suggest a decrease of inhibitory noradrenergic influence at the primary kindling site, which could play a role in kindling epileptogenesis.     

Long-term enhancement of K+-evoked release of L-glutamate in entorhinal kindled rats

Kainic acid- and K+-evoked in vitro release of endogenous amino acids from hippocampal slices were measured in rats kindled by entorhinal electrical stimulation. One month after completion of kindling, K+-evoked release of glutamate from hippocampal slices ipsilateral to the stimulus site was consistently greater than from both the contralateral hippocampus from kindled animals and all hippocampi of electroshock and sham-surgery control groups. Enhanced hippocampal neurotransmitter glutamate release may be involved in the permanent effects of electrical kindling.     

Effect of transient hippocampal inhibition on amygdaloid kindled seizures and amygdaloid kindling rate

In this study the effect of transient inhibition of the CA1 region of the dorsal hippocampus by lidocaine on amygdala kindling rate and amygdaloid kindled seizures was investigated. In experiment 1, rats were divided into four groups. In group 1, animals were implanted only with a tripolar electrode into the amygdala but in groups 2-4, two guide cannulae were also implanted into the CA1 regions of the dorsal hippocampi. Animals were stimulated daily to be kindled. In groups 3 and 4, saline or 2% lidocaine (1 microl/2 min) was also injected respectively into the hippocampus, 5 min before each stimulation. Results obtained showed that amygdala kindling rate and the number of stimulations to receive from stage 4 to stage 5 seizure were significantly increased in group 4. In experiment 2, lidocaine (1% and 2%) was infused (1 microl/2 min) into the hippocampus of amygdala kindled rats bilaterally and animals were stimulated at 5, 15 and 30 min after drug injection. Twenty four h before lidocaine injection, saline was also infused (1 microl/2 min) into the hippocampus as control. Obtained results showed that afterdischarge duration was reduced 5 min after lidocaine (1% and 2%) injection. Stage 5 seizure duration was also decreased 5 and 15 min after 2% lidocaine. Thus, it may be suggested that in amygdala kindling, activation of the hippocampal CA1 region has a role in seizure acquisition and seizure severity so that inhibition of this region results in decreasing of seizure severity and retards amygdala kindling rate.     

Resistance of immature hippocampus to morphologic and physiologic alterations following status epilepticus or kindling.

Seizures in adult rats result in long-term deficits in learning and memory, as well as an enhanced susceptibility to further seizures. In contrast, fewer lasting changes have been found following seizures in rats younger than 20 days old. This age-dependency could be due to differing amounts of hippocampal neuronal damage produced by seizures at different ages. To determine if there is an early developmental resistance to seizure-induced hippocampal damage, we compared the effects of kainic acid (KA)-induced status epilepticus and amygdala kindling on hippocampal dentate gyrus anatomy and electrophysiology, in immature (16 day old) and adult rats. In adult rats, KA status epilepticus resulted in numerous silver-stained degenerating dentate hilar neurons, pyramidal cells in fields CA1 and CA3, and marked numerical reductions in CA3c pyramidal neuron counts (-57%) in separate rats. Two weeks following the last kindled seizure, some, but significantly less, CA3c pyramidal cell loss was observed (-26%). Both KA status epilepticus and kindling in duced mossy-fiber sprouting, as evidenced by ectopic Timm staining in supragranular layers of the dentate gyrus. In hippocampal slices from adult rats, paired-pulse stimulation of perforant path axons revealed a persistent enhancement of dentate granule-cell inhibition following KA status epilepticus or kindling. While seizures induced by KA or kindling in 16-day-old rats were typically more severe than in adults, the immature hippocampus exhibited markedly less KA-induced cell loss (-22%), no kindling-induced loss, no detectable synaptic rearrangement, and no change in dentate inhibition. These results demonstrate that, in immature rats, neither severe KA-induced seizures nor repeated kindled seizures produce the kind of hippocampal damage and changes associated with even less severe seizures in adults. The lesser magnitude of seizure-induced hippocampal alterations in immature rats may explain their greater resistance to long-term effects of seizures on neuronal function, as well as future seizure susceptibility. Conversely, hippocampal neuron loss and altered synaptic physiology in adults may contribute to increased sensitivity to epileptogenic stimuli, spontaneous seizures, and behavioral deficits.     

Kindling increases the K(+)-evoked Ca2(+)-dependent release of endogenous GABA in area CA1 of rat hippocampus

The release of endogenous amino acids from hippocampal CA1 subslices under basal conditions and the release evoked by high potassium (50 mM K+) depolarization was studied during kindling epileptogenesis. Emphasis was put on the release of the amino acid neurotransmitters gamma-aminobutyric acid (GABA) and glutamate. Kindling was induced by tetanic stimulation of the Schaffer-collaterals/commissural fibers of the dorsal hippocampus of the rat. The calcium-dependent GABA release in the presence of high K+ was significantly increased (40-46%) in fully kindled animals, 24 h after the last seizure, in comparison to controls. At long-term, 28 days after the last seizure, the calcium-dependent GABA release was still significantly increased (45-49%). An increased release of GABA in kindled animals was still found when GABA uptake was blocked by nipecotic acid. In contrast, no significant alterations were encountered in the basal or high potassium induced release of the excitatory amino acids aspartate and glutamate. These results suggest that kindling epileptogenesis is accompanied by a specific and long-lasting enhancement of GABA exocytosis which may lead to a desensitization of the GABA receptor, and thus determine the increase of seizure sensitivity.     

Behavioral effects of high frequency electrical stimulation of the hippocampus on electrical kindling in rats

Experiments were designed to evaluate the effects of high frequency electrical stimulation (HFS) applied in ventral hippocampus during the hippocampal kindling process, as well as on the expression of fully kindled seizures and the refractoriness for subsequent convulsions during their postictal period. Male Wistar rats, stereotactically implanted in both ventral hippocampus, received daily bilateral HFS (pulses of 60 micros width at 130 Hz at subthreshold current intensity) during 1h immediately after each kindling stimulation (1s train of 60 Hz biphasic square waves, each 1 ms) during 40 days or until the kindled state was achieved. Rats were classified as follows: (a) Responder animals, who required low current intensity for HFS (208+/-38.2 microA), did not show progress of the kindling process and remained in stages II and III seizures. (b) Nonresponders rats, in which the current intensity for HFS was higher (434.5+/-51.7 microA), developed the kindling process as the kindling control group. When HFS was applied before the kindling stimulation in fully kindled rats, animals presented a reduced expression of the fully kindled seizures (nonresponders animals) and an enhanced refractoriness for subsequent seizures during the postictal period (kindling control and nonresponder animals). There was no correlation between the area where the HFS was applied and the effects induced. It was concluded that HFS at 130 Hz in ventral hippocampus is able to modify the epileptogenesis induced by the hippocampal kindling process and the refractoriness to subsequent seizures during the postictal period in rats.     

Common epileptic pathway in amygdaloid bicuculline and electrical kindling demonstrated by transferability

The transferability between amygdaloid bicuculline kindling and electrical kindling was studied in rats. Electrically kindled animals exhibited stage 5 generalized seizures on the first injection of bicuculline, in contrast to the 3–7 injections required in controls. Similarly, bicuculline-kindled animals reached stage 5 after significantly fewer electrical stimulations than controls; two-thirds of the bicuculline-kindled animals began in stage 1 but skipped stages 3 and 4 on their way to stage 5. These data indicate that a common generalization mechanism exists in both types of kindling, but the process of progression from local seizure to generalized seizure may be immature in bicuculline kindling.     

Amygdala kindling develops without mossy fiber sprouting and hippocampal neuronal degeneration in rats

Repeated electrical stimulation of limbic structures has been reported to produce the kindling effect together with morphological changes in the hippocampus such as mossy fiber sprouting and/or neuronal loss. However, to argue against a causal role of these neuropathological changes in the development of kindling-associated seizures, we examined mossy fiber sprouting in amygdala (AM)-kindled rats using Timm histochemical staining, and evaluated the hippocampal neuronal degeneration in AM-kindled rats by terminal deoxynucleotidyl transferase-mediated digoxigenin-11-dUTP nick end labelling (TUNEL). Amygdala kindling was established by 10.3 +/- 0.7 electrical stimulations, and no increase in Timm granules (neuronal sprouting) was observed up to the time of acquisition of a fully kindled state. However, the density and distribution of Timm granules increased significantly in the dentate gyrus compared with unkindled rats after 29 after-discharges or more than 10 kindled convulsions. In addition, no significant increase in TUNEL-positive cells was found in the hilar polymorphic neurons or in CA3 pyramidal neurons of the kindled rats that had fewer than 29 after-discharges. However, a significant increase of TUNEL-positive cells was found in the granule cell layer in the dentate gyrus of the stimulated side after 18 after-discharges or 10 kindled convulsions. Our result show that AM kindling develops without evidence of mossy fiber sprouting, and that mossy fiber sprouting may appear after repeated kindled convulsions, following death of the granule cells in the dentate gyrus.     

Rapid kindling of the hippocampus protects against neural damage resulting from status epilepticus

It has previously been reported that rats kindled via the standard kindling procedure do not exhibit the typical profile of neuropathology following status epilepticus. We wished to determine whether a 1-day rapid kindling procedure is also neuroprotective against cell damage resulting from prolonged seizure activity. We found that rats rapidly kindled from the dorsal hippocampus were more resistant to a kainic acid challenge 21-25 days after kindling than were unkindled control rats. Kindling prior to a kainic acid challenge also provided substantial protection against status epilepticus-induced damage in the CA3 region of the hippocampus and piriform cortex in most animals. Thus, despite the short kindling time period, rapid kindling is neuroprotective against status epilepticus-induced cell damage.     

Modulation of neurogenesis by targeted hippocampal irradiation fails to affect kindling progression

Changes in the rate of dentate granule cell neurogenesis and in the fate of newborn granule cells have been implicated in the development and progression of epilepsies. Strategies to normalize neurogenesis in chronic epilepsy models are thought to increase our understanding of the functional consequences of aberrant neurogenesis in the epileptic brain. Therefore, we modulated neurogenesis in an amygdala kindling paradigm in rats by targeted irradiation of the hippocampus using a medical linear accelerator device. Selective irradiation normalized the hippocampal cell proliferation rate in kindled animals. Both, in kindled and nonkindled rats the number of BrdU/NeuN‐labeled newborn neurons was reduced in response to irradiation. Whereas kindling resulted in a pronounced increase in the number of neuroblasts identified based on doublecortin‐labeling, irradiation prevented the expansion of the neuroblast population. Moreover, irradiation counteracted the kindling‐associated increase in hilar basal dendrites, and kept the fraction of cells with basal dendrites at control levels. Despite the efficacious modulation of neurogenesis, irradiation did not affect the rate of kindling progression. Both, the number of stimulations as well as the cumulative afterdischarge duration to reach respective seizure stages were comparable in animals with and without irradiation. In addition, pre‐ and postkindling thresholds as well as seizure parameters recorded at threshold stimulation remained unaffected by irradiation. In conclusion, the fact that the efficacious modulation of neurogenesis by irradiation did not exert any effects on kindling acquisition and kindled seizures suggests that newborn neurons do not critically contribute to the hyperexcitable state in the chronic epilepsy model used. © 2010 Wiley‐Liss, Inc.     

Development of long-lasting potentiation effects in the dentate gyrus during pentylenetetrazol kindling

In the present study kindling was induced in rats by repeated intraperitoneal injection of pentylenetetrazol (PTZ) once every 48 h. The resulting seizure stages were registered after each PTZ application. The development of PTZ-induced kindling and the time course of possible potentiation effects in the dentate gyrus were examined. The efficacy of perforant pathway transmission to the granule cells was tested in every second kindling session by measuring the monosynaptic evoked field potentials recorded in the dentate gyrus following single test stimuli of the perforant pathway at different times after PTZ injection in freely moving animals. The data suggest that establishment of a PTZ kindling is associated with the development of long-lasting potentiation of the field potentials. After completion of kindling it was demonstrated that kindled rats also show a diminished learning performance. The relationship between the development of potentiation phenomena in hippocampal substructures and learning impairment is discussed.     

Effects of age on kindling and kindled seizure-induced increase of benzodiazepine receptor binding

We examined the effects of age on kindled seizure development, benzodiazepine receptor binding, and kindled seizure-induced increases of benzodiazepine receptor binding. The results disclosed that: (1) development of kindling required greater numbers of stimulations in middle-aged than in young-adult animals; (2) in comparison to young-adult animals, middle-aged animals exhibited increased benzodiazepine receptor binding in the dentate gyrus of hippocampal formation: and (3) no age-related differences existed in the effects of seizures on benzodiazepine receptor binding. We suggest that senescence-related impairment of kindling development is due at least in part to alterations in the hippocampus, and that the increased benzodiazepine receptor binding in dentate gyrus may be one of the factors responsible for this impairment.     

Amygdalar kindling is associated with elevated zinc concentration in the cortex and hippocampus of rats

The reported convulsant properties of zinc and its association with hippocampal function prompted investigation of zinc levels during the induction and maintenance of kindling. Rats were fed zinc adequate diets during kindling, incited by daily amygdalar stimulation. The concentration of zinc in hippocampus was unperturbed during 3 stages of kindling induction when compared to either naive, sham surgery, or electroshock controls. In contrast, cortical zinc increased during kindling induction but returned to control levels in fully kindled animals. Two weeks after full kindling was established, the concentration of zinc in the hippocampus and overlying cortex increased significantly, in the absence of further electrical stimulation. The effect was restricted to the central nervous system inasmuch as zinc levels were unaffected in liver and other extracerebral tissues. Moreover, the zinc concentration was relatively unchanged during the 24 h period following a single electroconvulsive seizure, implying that the observed changes were not simply a postictal phenomenon. The results of this study suggest that long-lasting elevations in zinc are present after kindling is established. Whether this finding is related to the perpetuation of abnormal neuronal excitability or represents a compensatory response remains to be elucidated.     

Development of Kindled Amygdaloid Seizures After Section of the Forebrain Commissures in Rats

Repeated application of electrical stimulation to amygdala results in the progressive development and elaboration of clinical and electrographic seizures (kindling). The rate of kindling was compared in control rats and rats with various amounts of damage to the forebrain commissures. Partial or total tran-section of corpus callosum, hippocampal commissure, and anterior commissure did not retard the rate of kindled seizure development. In the few cases in which a retarded rate of kindling was observed, there was always evidence of unintended damage to rostral thalamic nuclei; no such damage was seen in forebrain-bisected rats that kindled at control rates. These results indicate that the forebrain commissures do not play an essential role in amygdaloid kindling, and they suggest that nuclei in the rostral thala-mus may participate in this phenomenon.     

Regional brain [3H]muscimol binding in kindled rat brain: a quantitative autoradiographic examination

Quantitative [3H]muscimol autoradiography was used to perform a comprehensive examination of the GABAA receptor site in entorhinal cortex kindled and handled control rats. Ninety-eight brain areas were analyzed 24 h or 28 days after the last kindled seizure. A significant post-kindling change was observed in only one area, the fascia dentata of the hippocampus, which showed an increase of 55% at 24 h, but not at 28 days. This acute change appeared in both the dorsal and ventral divisions of the hippocampus and in both the infrapyramidal and suprapyramidal blades of the fascia dentata. These data closely parallel the pattern previously obtained with [3H]flunitrazepam in the same animals. The comprehensive nature of this examination further suggests that the fascia dentata is the only site in the brain which shows altered GABAA binding after kindling. Although our data indicate that elevated [3H]muscimol binding is not a permanent feature of the kindled state, the possibility exists that the fascia dentata change observed at 24 h reflects a permanent alteration in the acute reactivity of hippocampal GABAA receptors to electrical stimulation.