Galanin and epilepsy

Neuroanatomical localization and physiological properties of galanin suggest that the peptide may be involved in the regulation of seizures. Indeed, administration of galanin receptor agonists into brain areas pertinent to the initiation and propagation of epileptic activity attenuated seizure responses under conditions of animal models of epilepsy; pharmacological blocking of galanin receptors exerted proconvulsant effects. Functional deletion of both galanin and galanin type 1 receptor genes produced transgenic mice with either spontaneous seizure phenotype, or with enhanced susceptibility to seizure stimuli. At the same time, overexpression of galanin in seizure pathways, using both transgenic and virus vector transfection techniques, hindered the epileptic process. Galanin exerts anticonvulsant effects through both type 1 and type 2 receptors, with distinct downstream signaling cascades. Several synthetic agonists of galanin receptors with optimized bioavailability have been synthesized and inhibited experimental seizures upon systemic administration, thus opening an opportunity for the development of galanin-based antiepileptic drugs.

Patterns of status epilepticus-induced substance P expression during development

Substance P, which modulates synaptic excitability, can be induced by a variety of stimuli. We studied the expression of hippocampal substance P in rats in using lithium-pilocarpine model of status epilepticus during development. Status epilepticus resulted in an age-specific manner of substance P expression that was anatomically distinctive in hippocampal subfields. Maximal induction of substance P immunoreactivity was seen in the CA1 region of the two-week-old rats, and progressively decreased in the three-, four-week-old rats and adults. Meanwhile, the number of substance P-immunoreactive neurons in the CA3 region and dentate granule cell layer was minimal in the two-week-old animals, but approximated the adult level in the three- and four-week-old rats. No substance P-immunoreactive axon terminals were seen in the strata pyramidale and lucidum in the CA3 region of the two-week-old rats, but they were found to progressively increase in the three-, four-week-old rats and adults. To confirm substance P expression after status epilepticus, we studied the expression of preprotachykinin-A mRNA in the hippocampus of the three-week-old rats by in situ hybridization. Two hours following injection of lithium-pilocarpine, preprotachykinin-A mRNA dramatically increased in the granule cells, as well as in the CA3 and CA1 pyramidal cell layers of the hippocampus. To evaluate the relationship between behavioral seizures and substance P induction, we used the NMDA receptor antagonist MK-801. Injection of MK-801 completely blocked lithium-pilocarpine-induced behavioral seizures and SP induction in the two-week-old rats. These results indicate that seizure activity selectively evokes age-dependent and region-selective expression of substance P.

Self-sustaining status epilepticus: a condition maintained by potentiation of glutamate receptors and by plastic changes in substance P and other peptide neuromodulators

We describe a model of self-sustaining status epilepticus (SSSE) induced by stimulation of the perforant path in free-running rats. In this model, seizures can be transiently suppressed by intrahippocampal injection of a blocker of alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid/ kainate synapses but return in the absence of further stimulation when the drug ceases to act. However, seizures are irreversibly abolished by blockers of N-methyl-D-aspartate receptors given locally or systemically. SSSE is enhanced by substance P and its agonists and blocked by its antagonists. SSSE induces novel expression of substance P-like immunoreactivity in hippocampal principal cells. These changes and those in other limbic peptides may contribute to the maintenance of SSSE and to the modulation of hippocampal excitability during epileptic seizures. NMDA

Epileptogenesis after status epilepticus reflects age- and model-dependent plasticity

Although epilepsy often begins in childhood, factors that contribute to the development of epilepsy as a consequence of status epilepticus (SE) during early development are poorly understood. We investigated animal models in which seizure-induced epileptogenicity could be studied. Rats undergoing self-sustaining SE induced by perforant path stimulation (PPS) at the ages of postnatal day 21 (P21) and P35 were compared with those subjected to SE by lithium and pilocarpine (LiPC). Although only one animal subjected to PPS at P21 developed chronic spontaneous seizures by several months of observation, all the animals subjected to PPS at P35 became epileptic. In the LiPC model, however, most of the rat pups subjected to SE at P21 became epileptic. Animals with spontaneous seizures showed increased inhibition in the dentate gyrus, a characteristic of the epileptic brain, with evidence of mossy fiber synaptic reorganization. Examination of circuit recruitment by c-Jun immunohistochemistry showed activation restricted to the hippocampus in P21 animals subjected to PPS, although extensive activation of hippocampal and extrahippocampal structures was seen in pups subjected to PPS-induced self-sustaining SE at P35 or LiPC SE at P21. These results demonstrate that the appearance of epilepsy as a consequence of SE is influenced by the type of insult as well as by age-dependent circuit recruitment.

Modulation of hippocampal excitability and seizures by galanin

Previous studies have shown that the expression of the neuropeptide galanin in the hippocampus is altered by seizures and that exogenous administration of galanin into the hippocampus attenuates seizure severity. To address the role of endogenous galanin in modulation of hippocampal excitability and its possible role in seizure mechanisms, we studied two types of transgenic mice: mice with a targeted disruption of the galanin gene (GalKO) and mice that overexpress the galanin gene under a dopamine-beta-hydroxylase promoter (GalOE). GalKO mice showed increased propensity to develop status epilepticus after perforant path stimulation or systemic kainic acid, as well as greater severity of pentylenetetrazol-induced convulsions. By contrast, GalOE mice had increased resistance to seizure induction in all three models. Physiological tests of hippocampal excitability revealed enhanced perforant path-dentate gyrus long-term potentiation (LTP) in GalKO and reduced LTP in GalOE. GalKO showed increased duration of afterdischarge (AD) evoked from the dentate gyrus by perforant path simulation, whereas GalOE had increased threshold for AD induction. Depolarization-induced glutamate release from hippocampal slices was greater in GalKO and lower in GalOE, suggesting that alterations of physiological and seizure responses in galanin transgenic animals may be mediated through modulation of glutamate release. Our data provide further evidence that hippocampal galanin acts as an endogenous anticonvulsant and suggest that genetically induced changes in galanin expression modulate both hippocampal excitability and predisposition to epileptic seizures.

Felbamate in experimental model of status epilepticus

PURPOSE

To examine the putative seizure-protective properties of felbamate in an animal model of self-sustaining status epilepticus (SSSE).

METHODS

SSSE was induced by 30-min stimulation of the perforant path (PPS) through permanently implanted electrodes in free-running male adult Wistar rats. Felbamate (FBM; 50, 100, and 200 mg/kg), dizepam (DZP; 10 mg/kg), or phenytoin (PHT; 50 mg/kg) were injected i.v. 10 min after SSSE induction. Electrographic manifestations of SSSE and the severity of SSSE-induced neuronal injury were analyzed.

RESULTS

Felbamate injected during the early stages of SSSE (10 min after the end of PPS), shortened the duration of seizures in a dose-dependent manner. Total time spent in seizures after FBM and 290 +/- 251 min (50 mg/kg), 15.3 +/- 9 min (100 mg/kg), and 7 +/- 1 min (200 mg/kg), whereas control animals spent 410 +/- 133 min seizing. This effect of FBM was stronger than that of DZP (10 mg/kg, 95 +/- 22 min) and comparable to that of PHT (50 mg/kg, 6.3 +/- 2.5 min). In the applied doses, FBM (200 mg/kg) was more effective than PHT (50 mg/kg) or DZP (10 mg/kg) in shortening seizure duration and decreasing spike frequency, when administered on the pleateau of SSSE (injection 40 min after the end of PPS). Anticonvulsant action of FBM was confirmed by milder neuronal injury compared with control animals.

CONCLUSIONS

Felbamate, a clinically available AED with a moderate affinity for the glycine site of the NMDA receptor, displayed a potent seizure-protective effect in an animal model of SSSE. These results suggest that FBM might be useful when standard AEDs fail in the treatment of refractory cases of SE.

Ontogeny of self-sustaining status epilepticus

Rat pups of ages of 20, 25, 30 and 35 postnatal days were subjected to the perforant-path stimulation model of status epilepticus (SE). This treatment resulted in age- and stimulus-frequency-dependent loss of inhibition in the dentate granule cell layer. Only 35% of the 20-day-old animals, but 88% of the 35-day-olds, progressed to self-sustaining status epilepticus (SSSE). Loss of inhibition as measured by 0.1-Hz paired-pulse testing and histologic damage that extended to the contralateral side, including both the hilus and some extrahippocampal limbic structures, were associated with SSSE. This model of SE differs from in vitro models of SE, in which immature animals show an increased susceptibility to epileptogenic stimuli, and provides us with a novel method to study epileptogenicity in the developing brain.

Resistance to excitotoxin-induced seizures and neuronal death in mice lacking the preprotachykinin A gene

Epileptic seizures are associated with increases in hippocampal excitability, but the mechanisms that render the hippocampus hyperexcitable chronically (in epilepsy) or acutely (in status epilepticus) are poorly understood. Recent evidence suggests that substance P (SP), a peptide that has been implicated in cardiovascular function, inflammatory responses, and nociception, also contributes to hippocampal excitability and status epilepticus, in part by enhancing glutamate release. Here we report that mice with disruption of the preprotachykinin A gene, which encodes SP and neurokinin A, are resistant to kainate excitoxicity. The mice show a reduction in the duration and severity of seizures induced by kainate or pentylenetetrazole, and both necrosis and apoptosis of hippocampal neurons are prevented. Although kainate induced the expression of bax and caspase 3 in the hippocampus of wild-type mice, these critical intracellular mediators of cell death pathways were not altered by kainate injection in the mutant mice. These results indicate that the reduction of seizure activity and the neuroprotection observed in preprotachykinin A null mice are caused by the extinction of a SP/neurokinin A-mediated signaling pathway that is activated by seizures. They suggest that these neurokinins are critical to the control of hippocampal excitability, hippocampal seizures, and hippocampal vulnerability.

Self-sustaining status epilepticus after a brief electrical stimulation of the perforant path: a 2-deoxyglucose study

Status epilepticus remains a life-threatening condition associated with a high mortality. In order to understand the pathophysiological mechanisms underlying sustained seizures, the identification of structures involved in seizure activity allowing to define epileptic networks may be important. Thus, local cerebral metabolic rate for glucose (LCMR(glc)) was measured in a rat model of self-sustaining status epilepticus (SSSE) induced by a brief intermittent perforant path stimulation of 30 min, using the quantitative [(14)C]2-deoxyglucose autoradiographic technique. SSSE induced a generalized bilateral increase in LCMR(glcs) affecting 27 of the 42 structures studied. Largest metabolic increases (>250%) were recorded in the hippocampus, amygdala, entorhinal and piriform cortices, and lateral septum. Marked metabolic activation was also seen in basal ganglia areas such as the substantia nigra, globus pallidus and accumbens nucleus. LCMR(glcs) in brainstem, some midbrain structures, and in the neocortex were not affected by SSSE. In conclusion, a brief stimulation of the hippocampus induced a reproducible limbic SSSE in 100% of the rats, characterized by the metabolic activation of limbic and extralimbic structures, known to be involved in this type of seizures. Therefore, this new model allowing the development of a well-defined SSSE, appears to be particularly suitable for further studies on the mechanisms involved in status epilepticus.

Substance P is expressed in hippocampal principal neurons during status epilepticus and plays a critical role in the maintenance of status epilepticus

Substance P (SP), a member of the tachykinin family, is widely distributed in the central nervous system and is involved in a variety of physiological processes including cardiovascular function, inflammatory responses, and nociception. We show here that intrahippocampal administration of SP triggers self-sustaining status epilepticus (SSSE) in response to stimulation of the perforant path for periods too brief to have any effect in control rats, and this SSSE generates a pattern of acute hippocampal damage resembling that known to occur in human epilepsy. The SP receptor (SPR) antagonists, spantide II and RP-67,580, block both the initiation of SSSE and SSSE-induced hippocampal damage and terminate established anticonvulsant-resistant SSSE. SSSE results in a rapid and dramatic increase in the expression of preprotachykinin A (a precursor of SP) mRNA and SP in principal neurons in CA3, CA1, and the dentate gyrus as well as in hippocampal mossy fibers. SP also increases glutamate release from hippocampal slices. Enhanced expression of SP during SSSE may modulate hippocampal excitability and contribute to the maintenance of SSSE. Thus, SPR antagonists may constitute a novel category of drugs in antiepileptic therapy.

N-methyl-D-asparate receptor antagonists abolish the maintenance phase of self-sustaining status epilepticus in rat

We examined the effects of blockers of N-methyl-D-asparate (NMDA) and +/- -alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA)/kainate receptors on the maintenance of self-sustaining status epilepticus (SSSE) induced in rats by brief intermittent electrical stimulation of the perforant path (PPS). Blocking of NMDA receptor at the PCP site by MK-801 (0.5 mg/kg, i.p.) or ketamine (10 mg/kg, i.p.) as well as at the glycine allosteric site by intrahippocampal 5,7-dichlorokynurenic acid (5,7-DCK, 10 nmol), rapidly and irreversibly aborted both behavioral and electrographic manifestation of SSS. Intrahippocampal injection of the AMPA/kainate receptor blocker 6-cyano7-nitroquinixaline-3-dione (CNQX, 10 nmol) transiently suppressed seizures, which reappeared 4-5 h later. We suggest that the maintenance phase of SSSE depends on activation of NMDA receptors and that NMDA receptor blockers may be a promising class of compounds for the treatment of status epilepticus.

Time-dependent decrease in the effectiveness of antiepileptic drugs during the course of self-sustaining status epilepticus

An animal model of self-sustaining status epilepticus (SSSE) induced in rats by brief intermittent perforant path stimulation (PPS) was examined with regard to the effects of two conventional antiepileptic drugs, diazepam and phenytoin. Thirty or sixty minutes PPS induced SSSE characterized by continuous behavioral and electrographic seizures lasting for hours. Both diazepam (10 mg/kg i. v.) and phenytoin (50 mg/kg i.v.) prevented the establishment of SSSE when administered 10 min prior to PPS. The injection of diazepam to seizing animals, 10 min after the end of 30 min PPS, was significantly less effective than pretreatment in attenuating SSSE. Administration of diazepam after 60 min PPS was characterized by a further decrease of its efficacy. Phenytoin was effective in aborting SSSE when injected 10 min after 30 min PPS. However, its efficacy was vastly decreased if injected 40 min after 30 min PPS, or 10 min after 60 min PPS. It is concluded that antiepileptic drugs, while highly effective in blocking the induction of SSSE, failed to affect its maintenance. SSSE induced by PPS is an advantageous animal model of refractory status epilepticus, which may be used in preclinical studies of novel antiepileptic drugs.

Galanin modulation of seizures and seizure modulation of hippocampal galanin in animal models of status epilepticus

We examined the role of hippocampal galanin in an animal model of status epilepticus (SE). Control rats showed abundant galanin-immunoreactive (Gal-IR) fibers in the dentate hilus, whereas no Gal-IR neurons were observed. Three hours after the onset of self-sustaining SE (SSSE), induced either by intermittent stimulation of the perforant path for 30 min (PPS) or by injection of lithium and pilocarpine, Gal-IR fibers disappeared in the hilus and remained absent for up to 1 week afterward. Twelve hours after the induction of SE by PPS or 3 hr after pilocarpine administration, Gal-IR neurons appeared in the hilus; these neurons increased in number after 1 d and gradually declined 3 and 7 d later. Galanin concentration in the hippocampus, measured by ELISA, significantly decreased on the plateau of SSSE and increased 24 hr after PPS. Galanin (0.05 nmol) injected into the hilus prevented the induction of SSSE, and 0.5 nmol of galanin stopped established SSSE. These effects were attenuated by galanin receptor antagonists (M35 > M40 >/= M15). 2-Ala-galanin (5 nmol), a putative agonist of galanin type 2 receptors, prevented but was unable to stop SSSE. M35 facilitated the development of SSSE when given before PPS. We suggest that hippocampal galanin acts as an endogenous anticonvulsant via galanin receptors. SE-induced galanin depletion in the hippocampus may contribute to the maintenance of seizure activity, whereas the increase of galanin concentration and the appearance of galanin-immunoreactive neurons may favor the cessation of SSSE. The seizure-protecting action of galanin SSSE opens new perspectives in the treatment of SE.

Self-sustaining status epilepticus after brief electrical stimulation of the perforant path

We examined the duration of intermittent perforant path stimulation (PPS) needed to induce self-sustaining status epilepticus (SSSE) in rats. Seven-minute PPS did not induce SSSE. Some rats receiving 15 min and all animals after 30 min PPS developed SSSE that continued for hours. The animals killed 3 days after SSSE showed extensive neuronal damage. Those which were allowed to survive for 6 weeks after SSSE displayed spontaneous seizures.

Blockers of NMDA receptor restore paired-pulse inhibition in the rat dentate gyrus lesioned by perforant path stimulation

The ¿dormant basket cell' hypothesis postulates, that after status epilepticus, inhibitory interneurons in the hippocampus are deafferented from their excitatory inputs. We provide evidence for active suppression of hippocampal inhibition. Status epilepticus-like perforant path stimulation induced loss of interneurons and loss of inhibition in the rat dentate gyrus. This loss was transiently reversed by antagonists acting at three different sites of the N-methyl-d-aspartate (NMDA) receptor. Intrahippocampal administration of gamma-aminobutyric acid (GABA) agonists, which were expected to increase inhibition, resulted in the opposite effect. Although the substrate for the observed effects of pharmacological agents cannot be certainly confined to the ¿dormant' basket cell, they suggest the expression of hippocampal circuits that actively suppress inhibition through an NMDA synapse.

Selective facilitation of kindled seizures from the amygdala after hippocampal lesions induced by perforant path stimulation

Intermittent electrical stimulation of the perforant path (PPS) for 24 h in anesthetized rats results in impairment of paired pulse inhibition, neuronal loss in the dentate gyrus and hippocampus, and delayed spontaneous seizures. One week after PPS, animals showed a dramatic decrease in afterdischarge threshold and increase in afterdischarge duration from the basolateral amygdala, whereas no changes in after-discharge properties were observed from the dentate gyrus. Animals also showed a remarkable facilitation of amygdala kindling, but not of perforant path kindling. After amygdala kindling, some animals showed spontaneous seizures. PPS may recruit amygdala into the epileptogenic circuit, resulting in "latent' kindling and development of spontaneous seizures.

Chronic epilepsy with damage restricted to the hippocampus: possible mechanisms

We studied the time course and possible mechanisms of the development of chronic epilepsy following unilateral stimulation of the perforant path. After 24 h of perforant path stimulation by a modified Sloviter method, lesions were restricted to the hippocampus, except for 2 of 24 rats with minimal entorhinal neuronal injury in layer 3. Lesions were exclusively ipsilateral in the polymorph layer of the hilus and in CA4-CA3C, predominantly ipsilateral in CA3, in CA1 and in the granule cell layer. Feedforward and feedback inhibition were studied by paired pulse stimulation. In the week following inhibition, there was complete loss of GABAA-mediated, short interstimulus interval (ISI)-dependent inhibition and frequency-dependent inhibition, and also of GABAB-mediated long ISI-dependent inhibition. Yet no spontaneous seizures were observed at that time. In the next four weeks, we saw no evidence of increasing excitatory drive such as would be expected from recurrent mossy fiber sprouting. On the contrary, there was progressive return of inhibition. By four weeks post-lesion, the majority of animals had developed spontaneous recurrent seizures, and/or seizures on 2 Hz stimulation (never seen in controls), in spite of complete or near-complete recovery of short ISI-dependent, GABAA-mediated inhibition. A small but significant loss of frequency-dependent inhibition persisted, but individual animals with complete recovery of frequency-dependent inhibition showed spontaneous seizures, suggesting that loss of GABAA-mediated inhibition was not the direct cause of chronic epilepsy. GABAB-mediated, long ISI-dependent inhibition continued to show a significant loss. The ratio of the population spike amplitude at 250 microA to the maximal population spike amplitude, a measure of granule cell excitability, was unchanged immediately after stimulation, but increased in the next few weeks in a manner identical to that seen in kindling, suggesting the possibility that during the transient loss of inhibition, spontaneous kindling had occurred. Intracellular recordings from granule cells in hippocampal slices prepared from these animals showed a significant loss of GABAB-mediated slow inhibitory postsynaptic potentials (IPSPs). These data show that the sequellae of unilateral status epilepticus with damage restricted to the hippocampus are sufficient to cause chronic recurrent seizures. There is a possibility that chronic epilepsy is not the direct result of the loss of inhibitory drive or of a sprouting-induced increase in excitatory drive, but represents plastic changes akin to spontaneous kindling, possibly facilitated by loss of GABAB-mediated inhibition.

Chemical kindling: implications for antiepileptic drugs - sensitive and resistant epilepsy models

The efficacy of phenobarbital (PB) and phenytoin (PHT) was evaluated against the convulsions in chemically (picrotoxin, PTX) kindled rats. Two protocols were used: assessment of seizures immediately after the completion of the kindling procedure and after the 2-week postkindling PTX-free period, as compared with acute PTX seizures. Kindled convulsions were more sensitive than acute PTX seizures to the antiepileptic action of PB and PHT. On the other hand, the "postkindling state" was characterized by the enhancement of the severity of the convulsions in comparison with both kindled and acute PTX seizures and dramatic increase in the resistance to the action of antiepileptic drugs (AEDs). It is concluded that the two paradigms--kindling proper and "postkindling"--could be applied as models for AED-sensitive and AED-resistant animal epilepsy models correspondingly.

Seizure-protecting effects of kyotorphin and related peptides in an animal model of epilepsy

Administration of peptides kyotorphin (KT), neokyotorphin (NKT), and d-ser-2-NKT into the lateral brain ventricle (10 nmol) increased the latency and attenuated the severity of picrotoxin-induced convulsions in rats. Anticonvulsive effects of the peptides were also observed after their administration into the CA1 hippocampi (2.5, 5, 10 nmol), with the order of potency d-ser-2-NKT-->NKT-->KT. When injected into the substantia nigra reticulata, the 10 nmol dose of NKT and d-ser-2-NKT displayed equal seizure-protecting effect, which was higher than that for KT. It is concluded that kyotorphin and its analogs provide structure-dependent, dose-dependent, and target site-dependent antiepileptic effect.

Influence of the neuropeptide galanin on active avoidance in rats

It was demonstrated in experiments on rats that the injection of the neuropeptide, galanin (200, 500, and 1000 ng), into the lateral cerebral ventricles induced a dose-dependent decrease in the number of successful attempts at avoidance in rats trained preliminarily to active avoidance by jumping. The preliminary administration of the cholinolytic, atropine (1 mg/kg, intraperitoneally), to the rats also caused an acceleration of the damping of the conditioned reflex and potentiated the indicated effect of galanin during the experiment. The use of the opioid antagonist, naloxone (1 mg/kg, intraperitoneally), did not exert an influence on the animals' behavior, but blocked the galanin-provoked acceleration of the extinction of the active avoidance habit. The intraperitoneal administration of a noncompetitive antagonist of excitatory amino acids, ketamine (10 mg/kg), did not influence the character of the animals' behavior nor the indicated effects of galanin. It was concluded that galanin possesses an amnestic action in the active avoidance test, and that this effect of the peptide is determined by the suppression of cholinergic and activation of opiatergic transmission in the central nervous system.

On the mechanism of antiepileptic peptides appearance in the cerebrospinal fluid

Intraventricular injection of cerebrospinal fluid obtained from cats with electroshock seizures resulted in suppression of generalized picrotoxin-induced seizures in rats. Antiepileptic action of cerebrospinal fluid was abolished by partial bilateral midbrain destruction that included the region of colliculi superii. Electrical stimulation of cerebellum in cats with such destructions caused the appearance of a pronase-sensitive antiepileptic substances in cerebrospinal fluid.

The influence of the delta-sleep-inducing peptide on convulsive activity

Data are presented in this paper on the influence of the delta-sleep-inducing peptide (DSIP) on various forms of convulsive activity. The capacity of this peptide to suppress convulsive activity in foci created in the cerebral cortex by the application of strychnine has been demonstrated in experiments on cats. It has been established in experiments on rats that DSIP determines the later development of the convulsive kindling syndrome, and prevents the development of convulsions in mice induced by bicuculline, picrotoxin, and corazol, but is devoid of such action in relation to thiosemicarbazide and strychnine. It was demonstrated that the anticonvulsant action of DSIP is associated with its influence on the reticular portion of the substantia nigra. The lowest level of this peptide itself has been discovered, in the reticular portion of the substantia nigra at the late stages of pharmacological kindling. It is inferred that DSIP may represent one of the factors of the endogenous control of the excitability of the brain.

[The effect of the neuropeptide galanin on active avoidance in rats]

Administration of galanin into the lateral brain ventricles induced a dose-dependent impairment of memory in the active avoidance test in rats. Atropine both induced the impairment of memory and potentiated the galanin amnestic effect. Naloxone had no such action as well as ketamine. Galanin seems to impair memory via suppressing cholinergic and activating opioid peptidergic transmission in the CNS.

[The effect of galanin on the experimental parkinsonian syndrome in rats induced by the intrastriatal administration of kainic acid]

Experiments in rats showed that intrastriatal administration of kainic acid in a dose of 100 but not 20 ng per side resulted in the development of behavioral disorders reminding those of Parkinsonian syndrome: bradykinesia, increased muscle rigidity, ptosis. Intrastriatal administration of galanin in doses of 10 and 50 ng induced only a decrease of locomotor activity in the "open field". When co-administered with kainic acid (20 ng), galanin displayed a dose-dependent potentiation of behavioral Parkinsonian-like disturbances the severity of which increased depending on the dose used. It is concluded that galanin potentiates the kainic acid-induced development of the generator of pathologically enhanced excitation in the striatum underlying the mechanisms of Parkinsonian syndrome. Thus, the increased galaninergic striatal activity could participate in the mechanisms of the above-mentioned CNS disorders.

[Synthesis and biological properties of new analogs of delta-sleep peptide. I. Antiepileptic effect]

To study structure-functional relationship in the series of DSIP, eleven DSIP analogues varying in positions 1, 2 and 6 were synthesized by the solid-phase method using both Boc- and Fmoc-approaches. The antiepileptic action of these analogues was compared with that of DSIP. The seizure activity was induced by the corazol or picrotoxin i. p. injection. Some analogues proved more efficient as antiepileptic agents than DSIP after their central (50 micrograms/kg in rats) and peripheral (1.0 mg/kg in mice) administration.

ANP(1-28), BNP(1-32) and CNP(1-22) increase the severity of picrotoxin-kindled seizure syndrome in rats

The administration of rANP(1-28) in doses of 1.0 and 2.0 nmol (but not 0.2 nmol) into the lateral cerebral ventricle (i.c.v) of rats preliminarily kindled with picrotoxin resulted in an increase of the severity of picrotoxin-kindled convulsions 24 hrs after injection of the peptide. I.c.v. injection of pBNP(1-32) also resulted in a proepileptic effect when it was applied in the same doses with a similar time course; the increased seizure severity was observed 48 hrs after injection of pBNP in a dose of 2 nmol. I.c.v. administration of CNP(1-22) in a dose of 2 nmol induced an increase in the severity of picrotoxin-kindled convulsions 24 and 48 hrs after application of the peptide. None of the peptides influenced the seizure syndrome immediately after the injections. It is presumed that the delayed proepileptic properties of the three natriuretic peptides could be caused by some of their stable fragments which accumulate during their metabolism.

Anticonvulsive effects of galanin administered into the central nervous system upon the picrotoxin-kindled seizure syndrome in rats

Galanin (2000, 1000 ng) administered into the lateral brain ventricle decreased the severity of picrotoxin-kindled convulsions in rats. The bilateral injection (200, 100 and 50 ng) of galanin into the hippocampus also evoked an anticonvulsive effect. When administered into the caudate nuclei or substantia nigra reticulata, galanin exerted anticonvulsive action only in a high dose (200 ng), whereas in the nucleus accumbens it did so in a low dose (50 ng). When administered into the ventral tegmental area in a dose of 50, 100 or 200 ng galanin failed to reduce the manifestations of picrotoxin-kindled seizures.

Effects of somatostatin and anti-somatostatin serum on picrotoxin-kindled seizures

The effects of somatostatin, administered into different areas of the brain were studied in preliminary picrotoxin-kindled rats. The injection of somatostatin into the lateral ventrical of the brain (i.c.v.) (1.8 nmol), the hippocampus (0.6 nmol) or the amygdala (0.6 nmol), resulted in a decrease in the severity of the picrotoxin-induced convulsions. Application of the peptide into the caudate-putamen or the substantia nigra reticulata did not alter the behavioural manifestations of the kindled seizures. The local injection of anti-somatostatin serum (1:5) into the hippocampus increased the severity of the kindled convulsions and blocked the anticonvulsive effect of somatostatin, given intraventricularly. Local administration of anti-somatostatin serum into the amygdala did not alter the kindled seizures and did not abolish the anticonvulsive action of somatostatin given intraventricularly. It is concluded that somatostatin could take part in endogenous control of seizures through a suppressant influence on limbic structures; the hippocampus could be a specific site for the antiepileptic action of somatostatin.

[The anticonvulsive action of the intranigral administration of the delta sleep-inducing peptide]

It is shown that injection of delta sleep-inducing peptide (DSIP) into the substantia nigra reticular part (SNrp) suppresses generalized convulsive activity induced in rats by picrotoxin and corazol injection but exerts no influence on the strichnine-induced seizures. The analogous DSIP injection causes the antiepileptic action in rats kindled through picrotoxin injections. The DSIP intranigral anticonvulsant action is blocked by naloxon and enhanced by haloperidol and yohimbin. It can be concluded that DSIP anticonvulsant action may be realized due to activation of SNrp-dependent opioid mechanisms and suppression of dopaminergic ones.

[The effect of the delta sleep-inducing peptide on seizure activity]

The delta-sleep-inducing peptide (DSIP) suppressed seizure activity in the cat cortical strychnine-induced seizure foci. The DSIP delayed development of corazol kindling in rats, prevented seizure induced with bicucullin and other agents in mice. The DSIP effect was shown to be realised through the action upon reticular black substance. The DSIP seems to take part in endogenous control of the brain excitability.

[Role of limbic structures in the mechanisms of post-traumatic epilepsy]

It was shown in the experiments on rats that intracerebroventricular administration of kainic acid (0.01, 0.05 microgram) after brain trauma, resulted in the occurrence of behavioral and electrographic convulsive disturbances; maximal expression of epileptic activity was obtained in entorhinal cortex and ventral hippocampus. Kainic acid induced epileptic reactions in nontraumatized rats only if injected in dose 0.1 microgram. Brain trauma did not lead to changes in seizures intensity induced by systemic picrotoxin administration. It is concluded that the formation of generator of pathologically enhanced excitation in limbic structures via increase of excitor glutamatergic neurotransmission is the important mechanism of traumatic epilepsy.

[Effects of neurotropin on seizure activity in picrotoxin kindling]

It is shown that both intracerebral and intraperitoneal neurotropin administration resulted in a decrease of seizure susceptibility of preliminary picrotoxin--kindled rats. On the other hand, neurotropin did not change the course of kindling development. Under conditions of acute picrotoxin--induced seizures it was observed that preliminary cycloheximide (protein-synthesis blocker) administration abolished anticonvulsant properties of neurotropin. It is concluded that anticonvulsant effects of neurotropin are realized via modulation of endogenous peptides synthesis and, in particular, cerulein.

Influence of cerebro-spinal fluid of picrotoxin kindled rats on seizure susceptibility and locomotor activity of recipients

Repeated picrotoxin administration (ip) in subthreshold doses in rats resulted in kindling of generalized seizures. Decrease of locomotor activity in kindled rats occurred in interictal periods. Intra-cerebroventricular microinjection to intact recipients of cerebrospinal fluid (CSF) of kindled but not intact rats or those after acute picrotoxin-induced convulsions, induced a decrease of locomotor activity and severity of acute picrotoxin induced seizures. These effects of CSF were blocked by naloxone pretreatment and were absent after injection of CSF to which protease inhibitors were not added. It is concluded that the release of endogenous opioid peptide substance(s) takes place in CSF of kindled animals which cause the interictal decrease of locomotor activity and may play the role of endogenous anticonvulsive factors controlling epileptic activity induction.

[The effect of the cerebrospinal fluid from rats subjected to picrotoxin-induced kindling on the motor activity and seizure susceptibility of recipient animals]

Experiments on rats have shown that repeated administration of primarily subthreshold dose of picrotoxin leads to the occurrence and progressive enhancement of seizure manifestations. During picrotoxin kindling the decrease of locomotor activity in interictal periods was recorded. Microinjection of cerebrospinal fluid (CSF) of kindled rats into lateral brain ventriculi of recipients resulted in decrease of locomotor activity and acute primarily generalized picrotoxin induced seizures. These effects of CSF were blocked by naloxone administration and were observed only if injecting CSF which was preliminarily treated with protease inhibitors. It is concluded that endogenous opioid substances accumulate in CNS during kindling and evoke a decrease in the locomotor activity. These substances act as anticonvulsant factors which control the development of epileptic activity.

[The role of the opiate mechanisms of the hippocampus and substantia nigra in the behavioral and convulsive disorders in picrotoxin-induced kindling]

It was shown in the experiments on rats that the repeated picrotoxin administration resulted in the kindling of generalized seizures. Generalized convulsions were followed by the development of either postictal depression or explosiveness. The injection of mu-opiate agonist met-enkephalin into hippocampus of kindled rats resulted in the increase in the severity of seizure reactions which were induced by picrotoxin and also in the increase in the number of animals with postictal explosiveness. The injection of dynorphin-A-1-13 (kappa-opiate agonist) into substantia nigra reticulata induced the locomotor depression which was like one in postictal period and resulted in the decrease of picrotoxin-induced seizures severity. It was concluded that mu-opiate system of hippocampus took part in the formation of generator of pathologically enhanced excitation in the structure during kindling and the development of seizure syndrome, providing also the postictal explosiveness. Kappa-opiate system of substantia nigra plays an important role in the activation of the antiepileptic system, limitation of seizures and the development of postictal depression.

[The formation of motor programs during pharmacological kindling]

In Wistar rats with the kindling phenomenon, the number of animals with three or more not stimulus-directed forms of swimming was increased. Obvious changes of swimming behaviour in these animals were also observed after intrastriatal injections of carbachol, apomorphine, haloperidol, muscimol and picrotoxin. These findings are discussed from the standpoint of a latent generator of pathologically enhanced excitation in the striatum which changed the ability of these rats to develop behavioral programs.

[Changes in the sleep-wakefulness cycle in experimental Parkinson's syndrome]

It was demonstrated in rat experiments that in modelling the akinetico-rigid parkinsonian syndrome by injecting kainic acid into the caudate nuclei the phases of wakefulness and light slow-wave sleep decreased while the phase of deep slow-wave sleep increased. In the tremorogenic from of the parkinsonian syndrome induced by reserpine the phases of wakefulness and deep slow-wave sleep decreased in the rats while the phases of light slow-wave and paradoxical sleep increased. In destruction of the substantia nigra with kainic acid the phase of paradoxical sleep reduced. The results of the study are discussed from the standpoint of the generator mechanisms of the development of neuropathological syndromes and the mechanisms of the interrelations of parkinsonism and epilepsy.

[Modeling of torsion dystonia through electric stimulation of the vermis cerebellum cortex]

It was shown in acute experiments on cats that electrical stimulation (ES) (100-300 Hz, 5.0-10.0 V) of cat's cerebellar vermal cortex (lobules V and VI) was followed by head deviation in the direction opposite to that side on which the animal was laying, posture and movement disturbances and also by simultaneously occurred contraction of musculus-antagonists of extremities. The tonic and posture disturbances were observed during 40-60 s after ES cessation. During this time in the zone of ES in cerebellar cortex the high-amplitude synchronized activity was registered which was due to generator of pathologically enhanced excitation (GPEE) formation. Intraperitoneal diazepam (0.5-1.0 mg/kg, 30 min before the observation) pretreatment suppressed GPEE formation that correlated with suppression of syndrome manifestations. The conclusion was made that cerebellar hyperactive cortex, which was due to GPEE induction, might have played the role of pathological hyperactive determinant structure of the described syndrome.

[Effects of extracts of different parts of the brain of kindled animals on seizure activity of recipient rats]

The peptide-containing fraction was emitted from the hippocampal and ventral mesencephalic region tissue of rats kindled with subconvulsant doses of corazol. Extracts were prepared by the help of hot acetic acid on the stage of generalized clonic-tonic seizure development. The intraventricular injection of VMR-extracts in relatively high dose increased seizure reactions which were induced in intact recipient rats by intraperitoneal corazol injection. The intraventricular injection of the extract in relatively low dose (100 times less) suppressed corazol-induced seizures in recipients. Data are discussed from the point of view of pathological epileptic system formation and the role played by peptides in supporting it's activity during pharmacological kindling.