Aberrant hippocampal neurogenesis after limbic kindling: Relationship to BDNF and hippocampal-dependent memory.

Seizures dramatically increase the number of adult generated neurons in the hippocampus. However, it is not known whether this effect depends on seizures that originate in specific brain regions or whether it is nonspecific to seizure activity regardless of origin. We used kindling of different brain sites to address this question. Rats received 99 kindling stimulations of the basolateral amygdala, dorsal hippocampus, or caudate nucleus over a 6-week period. After kindling, we counted the number of adult generated hippocampal neurons that were birth-dated with the proliferative marker bromodeoxyuridine (BrdU) to evaluate cell proliferation and survival under conditions of repeated seizures. Next, we counted the number of doublecortin immunoreactive (DCX-ir) cells and evaluated their dendritic complexity to determine if limbic and nonlimbic seizures have differential effects on neuronal maturation. We also quantified hippocampal brain-derived neurotrophin factor (BDNF) protein levels using an ELISA kit and assessed memory performance using a hippocampal-dependent fear conditioning paradigm. We found that limbic, but not nonlimbic, seizures dramatically increased hippocampal cell proliferation and the number of hilar-CA3 ectopic granule cells. Further, limbic kindling promoted dendritic outgrowth of DCX-ir cells and the number of DCX-ir cells containing basal dendrites. Limbic kindling also enhanced BDNF protein levels throughout the entire hippocampus and impaired the retrieval of fear memories. Collectively, our results suggest a relationship between limbic seizures, neurogenesis, BDNF protein, and cognition.

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.

The role of piriform cortex adenosine A1 receptors on hippocampal kindling.

INTRODUCTION: The hippocampus and piriform cortex have a critical role in seizure propagation. In this study, the role of adenosine A1 receptors of piriform cortex on CA1 hippocampal kindled seizures was studied in rats. METHODS: Animals were implanted with a tripolar electrode in the right hippocampal CA1 region and two guide cannulae in the left and right piriform cortex. They were kindled by daily electrical stimulation of hippocampus. In fully kindled rats, N6- cyclohexyladenosine (CHA; a selective adenosine A1 receptors agonist) and 1,3-dimethyl-8-cyclopenthylxanthine (CPT a selective adenosine A1 receptor antagonist) were microinfused into the piriform cortex. The animals were stimulated at 5, 15 and 90 minutes (min) after drug injection. RESULTS: Obtained data showed that CHA (10 and 100 microM) reduced afterdischarge duration, stage 5 seizure duration, and total seizure duration at 5 and 15 min after drug injection. There was no significant change in latency to stage 4 seizure. CPT at concentration of 20 microM increased afterdischarge duration, stage 5 seizure duration, and total seizure duration and decreased latency to stage 4 seizure at 5 and 15 min post injection. Pretreatment of rats with CPT (10 microM), 5 min before CHA (100 microM), reduced the effect of CHA on seizure parameters. CONCLUSION: These results suggested that activity of adenosine A1 receptors in the piriform cortex has an anticonvulsant effect on kindled seizures resulting from electrical stimulation of the CA1 region of the hippocampus.

Low-frequency stimulation of cerebellar fastigial nucleus inhibits amygdaloid kindling acquisition in Sprague-Dawley rats.

Low-frequency stimulation (LFS) of the kindling focus or the piriform cortex inhibits kindling epileptogenesis, but whether LFS of brain targets outside the limbic system has anticonvulsive actions remain unknown. The current study was designed to investigate the effect of LFS of the cerebellar fastigial nucleus (FN) on seizure progression induced by amygdaloid kindling. Stimulation at 1 Hz (15-min train of 0.1-ms pulses, 100 muA), but not at 3 Hz, in the ipsilateral FN immediately after the daily kindling stimulus (1-s train of 1-ms pulses at 60 Hz and 100-300 muA) significantly inhibited the seizure stage and afterdischarge duration in kindling acquisition. Neither 1 Hz nor 3 Hz stimulation of the contralateral FH had any significant effect. It is interesting that delaying delivery (immediately after the cessation of afterdischarge) of LFS in the ipsilateral FN accelerated the rate of kindling acquisition compared to controls. Our study suggests that LFS of targets outside the limbic system, such as the FN, may have a significant anti-epileptogenic action, and the effects of LFS depend on the frequency and timing of stimulation.

Radiation of the rat brain suppresses seizure-induced neurogenesis and transiently enhances excitability during kindling acquisition.

PURPOSE: Adult hippocampal neurogenesis is enhanced in several models for temporal lobe epilepsy (TLE). In this study, we used low-dose whole brain radiation to suppress hippocampal neurogenesis and then studied the effect of this treatment on epileptogenesis in a kindling model for TLE. METHODS: Half of the rats were exposed to a radiation dose of 8 Gy one day before the initiation of a rapid kindling protocol. Afterdischarge threshold (ADT), afterdischarge duration (ADD), clinical seizure severity, and inflammation were compared between groups. On the first and third day after radiation, rats were injected with 5'-bromo-2'-deoxyuridine (BrdU) to evaluate neurogenesis. Seven and 21 days after radiation, numbers of doublecortin (DCX) positive neuroblasts in subgranular zone and granule cell layer were compared between groups. RESULTS: We showed that radiation significantly suppressed neurogenesis and neuroblast production during kindling acquisition. Radiation prevented an increase in ADT that became significantly lower in radiated rats. On the third and fourth kindling acquisition day radiated rats developed more severe seizures more rapidly, which resulted in a significantly higher mean severity score on these days. Differences in ADD could not be demonstrated. DISCUSSION: Our results demonstrate that brain radiation with a relatively low dose effectively suppressed the generation of new granule cells and transiently enhanced excitability during kindling acquisition. Although seizure-induced neurogenesis was lower in the radiated rats we could not detect a strong effect on the final establishment of the permanent fully kindled state, which argues against a prominent role of seizure-induced neurogenesis in epileptogenesis.

Kindling epileptogenesis in immature rats leads to persistent depressive behavior.

Depression is a frequent comorbidity in epilepsy patients. A variety of biological factors may underlie epilepsy-associated depression. We examined whether kindling-induced chronic increase in seizure susceptibility is accompanied by behavioral symptoms of depression. Three-week-old Wistar rats underwent rapid kindling: 84 initially subconvulsant electrical stimulations of ventral hippocampus delivered every 5 minutes, followed by depression-specific behavioral tests performed 2 and 4 weeks later. Kindled animals exhibited a sustained increase in immobility time in the forced swim test and the loss of taste preference toward calorie-free saccharin, as compared with controls. Initial loss of preference toward the intake of calorie-containing sucrose was followed by the increased consumption at 4 weeks. At both time points, animals exhibited enhanced seizure susceptibility on test stimulations of the hippocampus. We conclude that neuronal plastic changes associated with the kindling state are accompanied by the development of depressive behavior.

Hippocampal partial kindling decreased hippocampal GABAB receptor efficacy and wet dog shakes in rats.

To test the hypothesis that GABA(B) receptor efficacy in the behaving rat decreases after partial hippocampal kindling, we measured GABA(B) receptor efficacy by the number of wet dog shakes (WDSs) induced by baclofen (5mM in 0.2muL of saline) infusion into the dorsal hippocampus; these WDSs were blocked by prior infusion of GABA(B) receptor antagonist CGP55845A. Rats were given 15 afterdischarges (ADs) evoked in CA1 over 3 days or control stimulations. The partially kindled rats (after 15 ADs) showed a significant decrease in baclofen-induced WDSs as compared to control rats, on days 1, 4 and 21 after kindling. In contrast, kindled and control rats did not show a significant difference in WDSs induced by hippocampal infusion of GABA(A) receptor antagonist bicuculline. Also, the number of WDSs induced after subcutaneous injection of serotonin-2A/2C agonist+/-1-(2,5-dimethoxy-4-iodophenyl)-2-aminopropane was not different between kindled and control rats on 4 and 21 days after kindling. We further tested the hypothesis that the decrease in hippocampal AD-induced WDSs during kindling is caused by a decrease in GABA(B) receptor efficacy. However, we found no convincing evidence to support the latter hypothesis since the AD-induced WDSs were not suppressed by hippocampal infusion of CGP55845A, with the exception that CGP55845A infusion into ventral hippocampus suppressed both hippocampal ADs and WDSs. Together with results derived from previous electrophysiological studies in vitro, it is suggested that a decrease of GABA(B) receptor, possibly GABA(B) autoreceptor, efficacy may explain the decrease of baclofen-induced WDSs after hippocampal kindling.

Influence of ionizing radiation on the course of kindled epileptogenesis.

Several clinical and experimental reports suggest that low-dose irradiation of an established epileptic focus can reduce the occurrence of spontaneous seizures. Conversely, some recent reports suggest that under some conditions low-dose irradiation may have disinhibitory effects on seizure expression. Here, we have investigated mechanistic aspects of this phenomenon in the kindling model of epilepsy by applying focal irradiation at various points during kindling development. Rats were kindled to stage 5 by afterdischarge-threshold electrostimulation of the left amygdala. Treatment groups were irradiated using a collimated X-ray beam (18 MV) either prior to kindling, at kindling stage 3, or at kindling stage 5, by exposure of the left amygdala to a single-fraction central-axis dose of 25 Gy. Generalized seizure thresholds (GSTs) were subsequently assayed at weekly intervals for 10 weeks and at monthly intervals for an additional 3 months, along with the severity of the evoked seizures. Irradiation produced no significant effects on seizure threshold, but did produce persistent changes in seizure severity which varied as a function of the timing of irradiation. Relative to sham irradiated controls, the occurrence of stage 6 seizures was significantly increased by irradiation prior to kindling, but was unaffected by irradiation at kindling stage 3, and significantly reduced by irradiation at kindling stage 5. Quantitative immunohistochemical assays for neuron and astrocyte densities within the amygdala and hippocampus revealed only subtle changes in neuronal density within the dentate granule cell layer. These results are discussed in relation to mechanisms of seizure- and radiation-induced plasticity.

Long-term kindling of the basolateral amygdala impairs copulatory behavior in male rats.

This experiment examined the consequences of long-term kindling of the basolateral amygdala on male sexual behavior and the frequency of both spontaneous wet dog shakes (WDS) and those induced by the 5-HT2A receptor agonist DOI. Results demonstrated that following 60 stimulations of the left basolateral amygdala over a 4-week period, male Long-Evans rats exhibited decrements in every aspect of sexual behavior. Specifically, latencies to mount, intromit and ejaculate were all prolonged following long-term kindling, and ejaculation frequencies were significantly reduced. Furthermore, spontaneous peri-copulatory WDS were increased in kindled rats, suggesting a possible role of the 5-HT2A receptor. However, countering this suggestion, there were no differences between sham and kindled rats on WDS induced by the 5-HT2A receptor agonist DOI. These results suggest that kindled rats may exhibit elevated levels of endogenous serotonin during exposure to a female rat, which would attenuate copulatory behavior, while concurrently increasing WDS expression.

Evidence for the perirhinal cortex as a requisite component in the seizure network following seizure repetition in an inherited form of generalized clonic seizures.

Perirhinal cortex (PRh) is strongly implicated in neuronal networks subserving forebrain-driven partial onset seizures, but whether PRh plays a role in generalized onset seizures is unclear. The moderate seizure severity substrain of genetically epilepsy-prone rats (GEPR-3s) exhibits generalized onset clonic audiogenic seizures (AGS), but following repetitive AGS (AGS kindling), an additional behavior, facial and forelimb (F&F) clonus emerges immediately following generalized clonus. F&F clonus is thought to be driven from forebrain structures. The present in vivo study used PRh focal blockade or extracellular PRh neuronal recording with simultaneous behavioral observations to examine the role played by PRh in AGS neuronal networks before and after AGS kindling in GEPR-3s. Bilateral microinjection of an NMDA receptor antagonist [2-amino-7-phosphonoheptanoic acid, AP7 (0.2-7.5 nmol/side)] into PRh did not affect generalized clonus before or after AGS kindling. However, complete and reversible blockade of only the F&F clonic seizure behavior was induced by AP7 (1 and 7.5 nmol) in AGS-kindled GEPR-3s. Significant increases in PRh neuronal responses to acoustic stimuli occurred after AGS kindling. Tonic PRh neuronal firing patterns appeared during generalized clonus before and after AGS kindling. During F&F clonus, burst firing, an indicator of increased excitability, appeared in PRh neurons. These neurophysiological and microinjection findings support a critical role of PRh in generation of this AGS kindling-induced convulsive behavior. These data are the first indication that PRh participates importantly in the neuronal network for AGS as a result of AGS kindling and demonstrate a previously unknown involvement of PRh in generalized onset seizures.

Correlation between shaking behaviors and seizure severity in five animal models of convulsive seizures.

Wet dog shakes (WDS) and head shakes (HS) are associated with experimentally induced convulsive seizures. We sought to determine whether these behaviors are correlated or not with major (status epilepticus (SE) or fully kindled animals) or minor (non-SE or partially kindled animals) seizure severity. WDS are directly correlated with SE induced by intracerebral star fruit extract (Averrhoa carambola) injection and with kindled animals in the amygdala fast kindling model. On the other hand, WDS are inversely correlated with SE induced by intracerebral bicuculline and pilocarpine injections. Systemic pilocarpine in animals pretreated with methyl-scopolamine barely induced WDS or HS. The role of shaking behaviors may vary from ictal to anticonvulsant depending on the experimental seizure model, circuitries involved, and stimulus intensity. The physical presence of acrylic helmets may per se inhibit the HS response. Also, methyl-scopolamine, a drug incapable of crossing the blood-brain barrier, can induce HS in animals without acrylic helmets.

Epilepsy induced by extended amygdala-kindling in rats: lack of clear association between development of spontaneous seizures and neuronal damage.

Most patients with temporal lobe epilepsy (TLE), the most common type of epilepsy, show pronounced loss of neurons in limbic brain regions, including the hippocampus, amygdala, and parahippocampal regions. Hippocampal damage in patients with TLE is characterized by extensive neuronal loss in the CA3 and CA1 sectors and the hilus of the dentate gyrus. There is a long and ongoing debate on whether this type of hippocampal damage, referred to as hippocampal sclerosis, is the cause or consequence of TLE. Furthermore, hippocampal damage may contribute to the progressive features of TLE. The present study was designed to determine whether development of spontaneous recurrent seizures (SRS) after extended kindling of the amygdala in rats is associated with neuronal damage. The kindling model of TLE was chosen because previous studies have shown that only part of the rats develop SRS after extended kindling, thus allowing to compare the brain pathology of rats that received the same number of amygdala stimulation but did or did not develop SRS. For extended kindling, rats were stimulated twice daily 3-5 days a week for up to about 280 stimulations. During long-term EEG/video monitoring, SRS were observed in 50% of the rats over the period of extended kindling. SRS often started with myoclonic jerks or focal seizures and subsequently progressed into secondarily generalized seizures, so that the development of SRS recapitulated the earlier kindling of elicited seizures. No obvious neurodegeneration was observed in the CA1 and CA3 sectors of the hippocampus, the amygdala, parahippocampal regions or thalamus. A significant bilateral reduction in neuronal density was determined in the dentate hilus after extended kindling, but this reduction in hilar cell density did not significantly differ between rats with and without observed SRS. Determination of the total number of hilar neurons and of hilar volume indicated that the reduced neuronal density in the dentate hilus was due to expansion of hilar area but not to neuronal damage. The data demonstrate that extended kindling does not cause any hippocampal damage resembling hippocampal sclerosis, but that SRS develop in the absence of such damage.

Effects of kindling and irradiation on neuronal density in the rat dentate gyrus.

Low-dose radiosurgery is presently in use as a treatment modality for focal epilepsy, but the mechanisms underlying the associated changes in seizure expression are poorly understood. We investigated whether total and parvalbumin expressing (PV+) neuronal densities within the hippocampus and amygdala are affected by analogous focal irradiation in amygdala-kindled rats. Adult rats were kindled by electrical stimulation through 10 stage 5 seizures. The kindled amygdala was then focally irradiated at 18 or 25 Gy, and generalized seizure thresholds were subsequently monitored for approximately 6 months. Histological and immunohistochemical assays of total and PV+ neuronal densities were performed bilaterally throughout the hippocampus and within the basolateral amygdala. PV+ neuronal densities were unaffected by kindling or irradiation in these regions. Kindling selectively reduced neuronal densities in the dentate granule cell layer, and medial CA3 pyramidal cell layer. Irradiation at 25 Gy, but not at 18 Gy, prevented or reversed this kindling-associated reduction in density.

Increased expression of the multidrug transporter P-glycoprotein in limbic brain regions after amygdala-kindled seizures in rats.

Increased expression of the multidrug transporter P-glycoprotein (Pgp; ABCB1) has previously been found in epileptogenic brain tissue from patients with pharmacoresistant temporal lobe epilepsy (TLE) as well as in the hippocampus and other limbic brain regions in the rat kainate model of TLE. Approaches to the quantification of Pgp expression have mainly been based on subjective visual estimation of the level of Pgp immunoreactivity in brain sections. In the present study, computer-assisted image analysis based on optical density (OD) measurements was used to examine immunohistochemical expression of Pgp in the kindling model of TLE. Sections from kainate-treated rats were used for comparison. Using diaminobenzidine as chromogen, Pgp was exclusively located in brain capillary endothelial cells, which was confirmed by double-labeling with an antibody against the endothelial glucose transporter (GLUT-1). After kainate-induced seizures, the intensity of endothelial Pgp staining significantly increased by 70-80% in the dentate gyrus. A significant, albeit less marked increase in Pgp expression in this area was also seen after amygdala-kindled seizures. Furthermore, Pgp was upregulated after kindling in the hilus of the dentate gyrus, the CA1 and CA3 sectors of the hippocampus, and the piriform and cerebral cortex. In kindled rats, most Pgp alterations occurred ipsilateral to the electrode in the basolateral amygdala. The data demonstrate that computer-assisted image analysis using OD is an accurate and rapid method to determine the relative amount of Pgp protein in brain sections and the effects of seizures on this multidrug transporter. The fact that Pgp overexpression in brain capillary endothelial cells occurs in two established models of difficult-to-treat TLE substantiates the notion that seizure-induced upregulation of Pgp contributes to multidrug resistance (MDR) in epilepsy.

Enhanced excitability induced by ionizing radiation in the kindled rat.

Evidence derived from both clinical and experimental investigations has suggested an influence of ionizing radiation on focal epileptogenicity. To better characterize this influence we applied focal ionizing radiation to a kindled epileptic focus in the rat amygdala. The right and left basolateral amygdala and right frontal cortex were implanted with concentric bipolar electrodes. Rats were kindled through a minimum of 10 stage 5 seizures by afterdischarge-threshold electrostimulation of the left amygdala, after which generalized seizure thresholds were determined prior to irradiation. The left amygdala was exposed to single-fraction central-axis doses of either 18 or 25 Gy using a beam-collimated (60)Co source (1.25 MeV). Generalized seizure thresholds were then redetermined at weekly intervals for 10 weeks and at monthly intervals for an additional 3 months. We observed no significant changes in seizure threshold during the postirradiation interval; however, we did observe persistent changes in seizure dynamics manifesting within the first week postirradiation. These consisted of an increased tendency for seizure activity to propagate into brain stem circuits during the primary ictus (i.e., "running fits") and an increased tendency for secondary convulsions to emerge postictally. These effects involving seizure dynamics have not been reported previously and appear to represent a radiation-induced disinhibition of one or more neural circuits. The disparity between these effects and earlier reports of seizure-suppressive effects resulting from analogous radiation exposures is discussed in relation to kindling and status epilepticus-induced pathogenesis within the hippocampus.