Amygdaloid kindling in glutamate transporter (GLAST) knockout mice

PURPOSE: Glutamate is the predominant excitatory neurotransmitter in the mammalian central nervous system. We previously reported abnormal glutamate release during seizures after kindling. GLAST and GLT-1 are astrocytic glutamate transporters, highly concentrated in the cerebellum and the telencephalon, respectively. We have investigated whether stages of amygdala kindling in knockout (KO) mice deficient in GLAST are the same as those of wild mice. METHODS: Electrodes were implanted into the basolateral amygdala, bilaterally, in C57BL/6J mice and GLAST KO mice under anesthesia. Once-daily stimulation was applied on one side through these electrodes, and bilateral EEG recordings were obtained. RESULTS: The behavioral manifestations of kindling in mice were (a) arrest of behavior, (b) head nodding, (c) forelimb clonus, (d) bilateral forelimb clonus with rearing, (e) tonic generalized convulsion with elevation of tail and falling with generalized tonic convulsion (GTC). Results of kindling: (a) Mutant mice kindled more slowly than wild-type mice (more stimulations were required to reach each stage in mutants); (b) after kindling was completed, additional stimulations induced shorter afterdischarges (ADs) in mutants than in wild-type mice; (c) Interictal epileptic spikes were more frequent in the mutants than in the wild-type mice, both in the stimulated amygdala and in the contralateral amygdala. CONCLUSIONS: GLAST KO mice, which are missing one type of astrocytic glutamate transporter, demonstrate kindling of an epileptic focus. However, the kindling is significantly slower in the GLAST mutant than in wild-type mice. These findings suggest that glutamate transport by the astrocytic GLAST transporter may have a role in normal epileptogenesis.     

Neuropilin-2 is overexpressed in the rat brain after limbic seizures

Structural rearrangement and synaptic reorganization are known to occur in the brain after seizures. If neuronal rearrangement after seizures always results in abnormal hyperexcitability, it would provide an accurate pathway to the appropriate target and as a result, it may be the mechanism of epileptogenesis. This study examined the mechanism of axon guidance in the mature rat brain after seizures by evaluating the expression of the axonal guidance molecule, neuropilin-2. We assessed the expression of neuropilin-2 by northern blotting and immunohistochemistry in rat with seizures created by kindling stimulation and kainate injection.The neuropilin-2 mRNA level was increased in the whole brain of the rats at 24 h after either type of seizure. Neuropilin-2 mRNA was not increased at 2 weeks after the last stimulation. Immunohistochemistry demonstrated that neuropilin-2 protein was increased in the dentate gyrus and the entorhinal cortex in the both seizure models. These findings suggested that there was overexpression of neuropilin-2 in the brains of mature rats with different types of seizure. Accordingly, neuropilin-2 might regulate remodeling after seizures as it does during the development of the hippocampal formation. Our findings suggest that axons may not project and outgrow 'aberrantly' after seizures, but may be regulated by the chemorepellent effect through neuropilin-2.     

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.     

Monoamines and seizures: microdialysis findings in locus ceruleus and amygdala before and during amygdala kindling

We used microdialysis to determine extracellular concentrations of norepinephrine (NE), dopamine (DA) and serotonin (5-HT) before and during a 1-day amygdala kindling paradigm. Subjects were young cats (<1 year old; n=8; 6 female, 2 male). Consecutive 5-min samples (2 microl/min infusion rate) were obtained from left amygdala and ipsilateral locus ceruleus complex (LC) under 3 experimental conditions lasting 1-h each (n=12 samples per cat per condition): (1) just before amygdala stimulation (baseline), (2) during focal afterdischarge (AD) and (3) during generalized AD. ADs were elicited by electrical stimulation applied to establish thresholds immediately before dialysate collection as well as during each sample collected in focal vs. generalized AD conditions. Sample concentrations were time-adjusted to correspond with sleep vs. waking state and/or focal vs. generalized ADs. Seizure activity was indexed by AD threshold (mA) and duration (s) as well as number and duration of specific clinically evident (behavioral) seizure manifestations. Main results were: (1) Lower baseline concentrations (fmoles per sample) of NE, DA and 5-HT correlated with subsequent increases in duration of focal and generalized AD as well as number of behavioral seizure correlates. (2) When compared to baseline levels, NE, DA and 5-HT concentrations significantly increased only in amygdala during focal AD and in both amygdala and LC during generalized AD. (3) NE and 5-HT concentrations were higher than DA at both collection sites and were selectively associated with increased wakefulness throughout the study.     

Gonadectomy unmasks an inhibitory effect of progesterone on amygdala kindling in male rats

Previous studies have suggested that the effects of progesterone on kindling in rats may be sexually differentiated, significant effects of physiological levels of progesterone being observed only in females. The present study demonstrates that this difference results from the hormones secreted by the testes. Thus, in orchidectomized males, progesterone induces a delay in the onset of amygdala-kindled seizures similar to that observed in females.     

AWD 140-190: a potent anticonvulsant in the amygdala-kindling model of partial epilepsy

PURPOSE: Evaluation of the effect of the new anticonvulsant drug, AWD 140-190 [4-(p-bromophenyl)-3-morpholino-1H-pyrrole-2-carboxylic acid methyl ester] on focally induced seizures and on epileptogenesis in the kindling model. METHODS: Effects of AWD 140-190 were studied in amygdala kindled rats after oral and intraperitoneal administration. In addition, the effect on kindling development was evaluated. In all experiments, behavioral changes in the rats in response to AWD 140-190 were monitored closely. RESULTS: AWD 140-190 exerted potent anticonvulsant activity against focal seizures. After intraperitoneal and oral administration in fully kindled rats, the substance dose-dependently increased the threshold for induction of afterdischarges starting at 15 mg/kg. AWD 140-190 only weakly influenced the seizure severity of the animals after stimulation at the elevated afterdischarge threshold current. No adverse effects were observed up to 30 mg/kg after intraperitoneal and oral administration in the open field and in the rotarod test. No differences were found between kindled and nonkindled rats when comparing neurotoxicity of AWD 140-190. Prolonged treatment with AWD 140-190 during kindling acquisition did not prevent kindling, but significantly retarded the development of fully kindled seizures during the treatment. CONCLUSIONS: This study demonstrates that AWD 140-190 has anticonvulsant effects in the amygdala kindling model in rats, suggesting that the substance is particularly effective against partial seizures. AWD 140-190 is orally active and devoid of neurotoxic effects in anticonvulsant doses, thus indicating that this compound has potential for antiepileptic therapy. AWD 140-190 retards the kindling development during the treatment. This effect could be explained by the acute anticonvulsant effect of the substance.     

Autoradiographic analysis of [S]TBPS binding in entorhinal cortex-kindled rat brains

A quantitative autoradiographic analysis of [³⁵S]t-butylbicyclophosphorothionate (TBPS) binding to the γ-aminobutyric acid (GABA)- mediated chloride ionophore was carried out in 104 brain areas of entorhinal cortex-kindled and control rats. Subjects were sacrificed either 24 h or 28 days after the last kindled seizure. Kindled subjects in the 24 h group showed reductions in mean [³⁵S]TBPS binding in the lateral nucleus of the amygdala (−31%), the infralimbic cortex (−14%), and the paracentral nucleus of the thalamus (−22%). At 28 days, reductions in binding were observed in the infralimbic cortex (−15%) and the paracentral nucleus of the thalamus (−18%). These data suggest that repeated seizures (kindling) modify the GABA-mediated chloride ionophore, and that in some brain areas related to seizure generalization the modifications are very long lasting.     

Cysteamine suppresses kindled seizures in pentylenetetrazol-kindled rats

Rats were kindled by intraperitoneal injection of pentylenetetrazol (PTZ) (30 mg/kg) every 48 h. Once kindled, animals received a single injection of cysteamine (200 mg/kg) and subsequent responses to PTZ were observed. Cysteamine, an agent which depletes brain somatostatin and suppresses kindled seizures in amygdaloid-kindled rats, markedly suppressed the severity of PTZ-induced seizures in PTZ-kindled rats as well. However, it did not alter the convulsive response of non-kindled rats to a submaximal convulsive dose (50 mg/kg) of PTZ. The results support a role for somatostatin in kindling.     

Repetitive audiogenic seizures cause an increased acoustic response in inferior colliculus neurons and additional convulsive behaviors in the genetically-epilepsy prone rat

Previous studies indicate that daily repetition of audiogenic seizures (AGS) leads to audiogenic ‘kindling’ with increased seizure duration and additional seizural behaviors. The present study examined the neuronal correlates of this phenomenon. Extracellular single neuron firing and concomitant convulsive behaviors associated with 14 repetitive AGS were evaluated in the genetically epilepsy-prone rat severe seizure strain (GEPR-9). An increase in the number of acoustically-evoked action potentials in neurons of the central nucleus of inferior colliculus OW was observed by the second day of AGS repetition, and peaked at day four. The ICc responses remained at similar enhanced level through day 14. ICc neuronal responses were completely absent for approximately two min post-ictally after a single AGS in all animals, but 80% of the animals undergoing repetitive AGS consistently exhibited neuronal firing in this post-ictal period. Post-tonic clonus and an increased duration of post-ictal behavioral depression were also observed with repetitive AGS. The increased ICc neuronal firing was observed prior to the appearance of the post-tonic clonus component of repetitive AGS. This suggests that the ICc neuronal firing increase may subserve, at least, the initial increase in AGS severity. However, changes in neuronal firing in nuclei of the neuronal network for AGS efferent to the ICc may be responsible for the increased AGS severity that occurs after the fourth day of AGS repetition.     

Effect of daily saline, drug or blank injections on the susceptibility to the convulsant effect of drugs.

The daily intraperitoneal injection to rats of doses of metrazol (30 mg/Kg), strychnin sulfate (1 mg/Kg) or picrotoxin (1.2 mg/Kg) that were initially subconvulsant, caused after a number of days which varied with the drug, clonic convulsions in a high percentage of the animals. However, after 18 daily injections of saline there was a similar increase of seizure susceptibility to the 3 drugs. The daily handling of rats as for injection, either followed or not by actual abdominal pricking (blank injection), had a similar though less pronounced effect. In animals that were housed in the same room where the others were tested, but which were not handled, the above mentioned doses of metrazol, strychnine and picrotoxin had no convulsant effect. These results indicate that the procedure of submitting rats to daily intraperitoneal injections is not as unconsequential as is usually thought to be, and that it may induce neurological changes.