Brain norepinephrine and convulsions in the genetically epilepsy-prone rat: sex-dependent responses to Ro 4-1284 treatment

Seizure predisposition in the Genetically Epilepsy-Prone Rat (GEPR) is at least partially dependent on central nervous system noradrenergic deficits. We have previously shown that moderate seizure GEPRs (GEPR-3) experience an increase in seizure severity after receiving Ro 4-1284, a monoamine vesicle inactivating drug. We are now reporting the effect of this drug on severe seizure GEPRs (GEPR-9). Motives for this study were: (a) to determine the effects of further depletion of innately deficient monoaminergic stores on seizure latencies and (b) to investigate whether a previously documented seizure severity difference between the sexes is related to the defective monoaminergic system in these subjects. GEPR-9s with known seizure history were tested for latency to onset of running phase and convulsion 45 minutes after Ro 4-1284 or saline administration. Brain norepinephrine levels were also determined. Ro 4-1284 caused severe depletion of monoamines in all brain areas assayed in both sexes of GEPR-9s and also caused a reduction in the latencies for onset of running and convulsion. The drug-induced norepinephrine depletion across the brain areas surveyed was significantly greater in females than in their male littermates. These observations prompt us to postulate that noradrenergic neurons in female GEPR-9s are functionally different from those in males and that this difference is detected in the differential effectiveness of Ro 4-1284 between the two sexes. Also, the influence of gonadal hormones on seizure predisposition and on the neurochemical actions of Ro 4-1284 may be different in GEPR-9 males and females.     

Role of brain 5-hydroxytryptamine in audiogenic seizure in the rat

The effects of various treatments on brain 5-hydroxytryptamine (5-HT) levels were compared to their effects on audiogenic seizure (AGS) intensity. Although some of these procedures also altered norepinephrine (NE) and dopamine (DA) concentrations, it was possible to observe differences in the depletion of these 2 catecholamines and 5-HT. The data indicated that depletion of brain 5-HT itself enhances AGS, whereas an increase in the concentration of this amine above physiologic levels diminishes the intensity of seizure. It appears that 5-HT exerts an inhibitory effect in the brain which limits spread of the seizure discharge. Thus, depletion of this amine disrupts inhibitory activity, allows more efficient spread of seizure activity in the brain and increases severity of AGS.     

Noradrenergic and serotonergic determinants of seizure susceptibility and severity in genetically epilepsy-prone rats

Pharmacological studies demonstrate a reciprocal relationship between both noradrenergic and serotonergic transmission and audiogenic seizure severity and susceptibility in the genetically epilepsy-prone rat (GEPR). In contrast, drug-induced changes in the neurochemical indices of dopaminergic activity do not result in alterations in seizure severity. These pharmacological investigations led to the hypothesis that both noradrenergic and serotonergic neurons are capable of regulating seizure severity in the GEPR. Pharmacological investigations also provided evidence that monoaminergic neurons serve as determinants of seizure susceptibility in these epileptic animals. The GEPR is susceptible to environmentally-induced seizures which cannot be precipitated in neurologically normal subjects. Drug studies suggest that monoaminergic decrements serve as one set of susceptibility determinants. However, non-monoaminergic abnormalities also play important roles in the seizure predisposition which characterizes the GEPR. Pathophysiological studies have confirmed and extended the concepts generated by the pharmacological investigations. Noradrenergic and serotonergic deficits do indeed characterize the seizure naive state of the GEPR. These studies have provided a basis for tentative identification of areas of the brain in which monoaminergic abnormalities regulate seizure severity and susceptibility. Monoaminergic defects in some areas such as the thalamus may regulate both susceptibility and severity. In other areas, defects may regulate only severity or susceptibility. In the striatum, noradrenergic defects do not appear to be present and probably are not determinants of the epileptic state of the GEPR.     

Neurotransmitter abnormalities in genetically epileptic rodents

A growing body of evidence supports a pathophysiological role for norepinephrine (NE) and serotonin in the regulation of seizures in the genetically epilepsy-prone rat (GEPR). Other evidence indicates that gamma-aminobutyric acid (GABA) and taurine may also participate in the seizure regulation process. Innate deficits in NE and serotonin appear to be causes of the genetically determined seizure-prone states of the GEPR, whereas abnormalities in GABAergic systems and taurine metabolism may represent inadequate attempts of the central nervous system to compensate for the seizure-prone state in these rats. In audiogenic seizure-susceptible (AGS) mice, evidence suggests a role for dopamine as well as GABA and possibly serotonin. NE may contribute to the regulation of seizures in AGS mice, but consistent evidence for a primary role for this monoamine is lacking. It is suggested that there is no single common neurotransmitter abnormality underlying genetic seizure disorders in humans or other animals and that the GEPR and the AGS mouse may both serve as good models for study of the neurochemical abnormalities that underlie the different human epilepsies.     

Ontogeny of susceptibility to the convulsant, Ro 5-4864, and its relationship to audiogenic seizure susceptibility in inbred mice

The postnatal development of susceptibility to the convulsant effects of Ro5-4864 (4'-chlorodiazepam) was characterized in two inbred mouse strains (DBA/2J and BALB/c ByJ) which as adults differ markedly in their response to this convulsant. Onset of susceptibility to a dose of Ro5-4864 which caused a high frequency of clonic seizures in adults was observed at 10 days of age in DBA/2 mice, but not until 35 days in BALB/c By mice. At 14 days of age an abrupt increase in susceptibility to Ro5-4864-induced tonic seizures was found in DBA/2 but not BALB/c By mice. Both the peak of tonic seizure susceptibility (21 days) and the time course of its subsequent age-dependent decline closely paralleled the change in audiogenic seizure susceptibility in the DBA/2 strain. PK11195 (40 mg/kg) blocked Ro5-4864 (25 mg/kg)-induced, age-dependent tonic seizures but had no effect on clonic seizure induction in the same mice. These observations establish that both the susceptibility to Ro5-4864 in adult mice and the postnatal time course for development of susceptibility to this convulsant are inherently different in these two strains of mice. The lack of coincidence between the developmental onset of susceptibility to Ro5-4864-induced seizures and the onset of supersensitivity to Ro5-4864-induced tonic seizures during the period of peak audiogenic seizure susceptibility in DBA/2 mice implies that more than one neurochemical mechanism is involved in the ability of Ro5-4864 to induce seizures in this strain. However, the blockade of Ro5-4864-induced tonic seizures by PK11195 suggests that peripheral type benzodiazepine receptors may mediate this effect.     

Genetic Association Between Ca2+-ATPase Activity and Audiogenic Seizures in Mice

Ca2+-ATPase activity was studied in fresh brain stem homogenates of the audiogenic seizure (AGS)-resistant C57BL/6 and AGS-susceptible DBA/2 inbred strains and in 21 B6 X D2 recombinant inbred strains. A highly significant negative correlation was found between Ca2+-ATPase activity and AGS susceptibility among these strains. In general, strains with low Ca2+-ATPase activities were more AGS-susceptible than strains with high activities. Further, Ca2+-ATPase activity appears to be influenced by a major gene associated with the Ah locus. This gene is designated Caa for Ca2+-ATPase activity and is different from Ias, which is closely linked to the Ah locus. Ias influences AGS spread by a yet unknown biochemical mechanism, whereas Caa may influence AGS susceptibility by regulating Ca2+-ATPase activity in brain tissue.     

听原性惊厥易感大鼠下丘GluR2的表达及QR位点编辑水平

听原性惊厥易感大鼠是强直 -阵挛惊厥大发作的一种模型 .一般认为 ,下丘是听原性惊厥发作神经元网络的启动部位 .采用RT PCR、Western印迹、免疫组织化学等方法观察了听原性惊厥易感大鼠 (P77PMC)一次惊厥发作与惊厥点燃状态下AMPA受体亚基GluR2在下丘内表达的改变 ,并采用限制性酶切方法分析了GluR2Q R位点mRNA编辑水平的改变 .研究结果显示 ,一次惊厥发作后下丘内GluR2表达无明显改变 ,惊厥点燃后下丘内GluR2表达降低 ,一次惊厥发作及惊厥点燃状态下GluR2Q R位点处于编辑成熟状态 .提示 ,GluR2表达降低参与了点燃状态下的惊厥发作 ,在听原性惊厥易感大鼠惊厥发作机制中不涉及下丘内GluR2Q R位点编辑水平改变 .     

LACK OF ABNORMALITY IN BRAIN AROMATIC AMINES IN RATS AND MICE SUSCEPTIBLE TO AUDIOGENIC SEIZURE*

The levels of certain amines (catecholamines, 5-HT, and ‘histamine’) and of certain enzymes (tyrosine hydroxylase, tryptophan hydroxylase, ChAc, or AChE) in whole brain or selected brain areas of rats and mice susceptible to audiogenic seizure have been compared with the levels in matched groups of non-sensitive animals. Sensitive groups included both those where susceptibility is inborn and those where it is induced by administration of methionine sulphoximine or thiosemicarbazide. No significant difference was found which could be correlated with susceptibility to audiogenic seizure.     

Convulsant component of a depressant benzodiazepine

The convulsant influence of high doses of diazepam, in the presence of the benzodiazepine receptor antagonist Ro 15-1788, was studied in rats. Animals were implanted with permanent cortical screw electrodes for EEG recording. EEG spiking and accompanying clonic activity was observed in rats receiving greater than or equal to 200 mg/kg diazepam, followed 10 minutes later by Ro 15-1788 (20 mg/kg). Pentylenetetrazole and picrotoxin seizure thresholds, measured during constant rate iv infusion, were significantly lowered by pretreatment with diazepam (250 mg/kg) and Ro 15-1788 (20 mg/kg) administered 30 and 20 minutes, respectively, before seizure threshold measurement. It is proposed that this convulsive activity of diazepam is mediated through the picrotoxinin receptor.     

Cerebral, cerebellar, and brain stem gangliosides in mice susceptible to audiogenic seizures

Abstract— The quantitative and qualitative distribution of gangliosides was investigated in the cerebrum, cerebellum and brain stem of audiogenic seizure resistant (C57BL/6J) and susceptible (DBA/2J) mice at 21 days of age. The concentration of gangliosides (μg/unit weight) was higher in the DBA cerebrum and brain stem, but lower in the DBA cerebellum compared to the concentration in C57 mice. In general, the brain water content was lower in DBA mice than in C57 mice. The distributions of a number of gangliosides were found to be different between the two strains and the differences were often in the same direction across the three brain regions. The most consistant and significant difference in ganglioside pattern observed between the strains was the higher concentration of G_M1 in all three regions of the DBA brain. These results suggest that DBA mice have a more heavily myelinated CNS than C57 mice. The relationship of these observations to inherent audiogenic seizure susceptibility is discussed.     

Morphine mydriasis in mice.

In mice, morphine produces dose-dependent mydriasis. The mydriatic effect does not depend upon the integrity of the sympathetic system, and interference with central catecholamines or serotonin also does not abolish the response. Ro 4-1284, a neurotransmitter depletor, causes miosis and inhibits completely the response to morphine. This effect may possibly be related to depletion of histamine, GABA, or other neurotransmitter.     

The influence of neonatal ketamine injection on pain sensitivity and audiogenic seizures in adult rats

The remote effects of neonatal (on the 3d-to-9th postnatal days) ketamine injections (10 and 50 mg/kg in 20 microliters of distilled water, s.c.) were analyzed in adult Wistar, WAG/Rij, and KM (a strain with high audiogenic sensitivity) rats. Both ketamine and water injections increased pain sensitivity in adult rats. Neonatally injected water increased the mean score of seizures in Wistar and WAG/Rij, whereas ketamine water solution injected in the dose of 50 mg/kg did not change the seizure intensity (as compared to the intact control). Consequently, ketamine significantly reduced the mean score of the audiogenic seizure fit without change in its latency. In highly sensitive KM rats the neonatally injected ketamine (50 mg/kg) significantly shortened the mean latency of the fit onset, and fit stages developed faster. Thus, the neonatal ketamine injection increased the audiogenic seizure susceptibility of brain structures in KM rats.     

Laboratory rat selection for the trait "the absence of audiogenic seizure proneness"

The hybrids between Krushinsky-Molodkina (KM) inbred strain, selected for high predisposition to audiogenic epilepsy (AE), and Wistar rats non-prone to audiogenic seizure were the initial population for selection. Rats were selected for the trait "the absence of audiogenic seizure proneness". The creation of such strain in which the significant proportion of animals develop no AE in response to sound and share partly the genetic background of the KM strain is very important for the correct use of RV strain as the laboratory model of seizure states. As alleles which determine the AE proneness are recessive the selection for the "opposite" trait proceeds necessarily slow.     

Laboratory rat selection for the trait “the absence of audiogenic seizure proneness”

The hybrids between Krushinsky-Molodkina (KM) inbred strain, selected for high predisposition to audiogenic epilepsy (AE), and Wistar rats non-prone to audiogenic seizure were the initial population for selection. Rats were selected for the trait ??the absence of audiogenic seizure proneness??. The creation of such strain in which the significant proportion of animals develop no AE in response to sound and share partly the genetic background of the KM strain is very important for the correct use of KM strain as the laboratory model of seizure states. As alleles which determine the AE proneness are recessive the selection for the ??opposite?? trait proceeds necessarily slow.     

Confirmation of the influence of a Chromosome 7 locus on susceptibility to audiogenic seizures

Mouse strain differences in susceptibility to audiogenic seizures (AGS) are due to allelic differences at multiple genetic loci. Three loci that influence susceptibility to AGS have been mapped on Chromosomes (Chr) 12, 4, and 7 (Asp-1, Asp-2, and Asp-3, respectively). Here we report evidence that confirms linkage of Asp-3 to c on Chr 7 and parental effects on AGS susceptibility, but not genomic imprinting of Asp-3.     

Genetic Study of Cationic ATPase Activities and Audiogenic Seizure Susceptibility in Recombinant Inbred and Congenic Strains of Mice

Total, Mg2+, and Na+, K+ ATPase activities were studied in fresh brain homogenates of the audiogenic seizure (AGS)-resistant C57BL/6J (B6) and AGS-susceptible DBA/2J (D2) inbred strains and in 13 B6 X D2 (BXD) recombinant inbred (RI) strains. These activities were also studied in the D2.B6-Iasb congenic mice, that are similar genetically to D2 mice, except for the Iasb gene which inhibits the spread of AGS activity. The total and Mg2+ ATPase activities of the brainstem were significantly lower in the D2 than in the B6 mice at 21 days of age. No differences were found between these strains for Na+,K+ ATPase activity. The total, Mg2+, and Na+,K+ ATPase activities in the B6 brainstem did not change noticeably from 21 to 80 days of age. In the D2 brainstem, however, the Mg2+ activity increased with age, and the Na+,K+ ATPase activity decreased from 30 to 80 days of age. No genetic associations could be found between AGS susceptibility and total or Mg2+ ATPase activities in the D2.B6-Iasb mice or among the 13 BXD RI strains. Hence, differences in genetic background, rather than differences in AGS susceptibility, can account for the lower ATPase activities in 21-day-old D2 mice. Further, the Mg2+ and Na+,K+ ATPase activities appear to be regulated by more than one gene. This study emphasizes the utility of RI and congenic strains for testing the biochemical basis of AGS susceptibility in mice.     

Effect of MPTP on Dopamine Metabolism in Ames Dwarf Mice

Hypopituitary dwarf mice exhibit a heightened antioxidative capacity and live extensively longer than age-matched controls. Importantly, dwarf mice resist peripheral oxidative stress induced by paraquat, and behaviorally, they maintain cognitive function and locomotor activity at levels above those observed in old wild-type animals. We assessed monoaminergic neurotransmitters in nigrostriatal tract and cerebellum after the administration of the dopaminergic neurotoxin, MPTP. There was no significant change in mitochondrial monoamine oxidase (MAO)-B and total MAO activity in the substantia nigra and nucleus caudatus putamen of wild-type and dwarf mice. Coenzymes Q-9 and Q-10 were present in similar quantities, as were dopamine, norepinephrine, and serotonin levels in the cerebellum and nigrostriatal tract. MPTP set off tremor, hind limb abduction, and straub tail behavior and induced significant dopamine depletion in the striatum of both dwarf and normal mice. This study shows that the MAO activity and the coenzyme content of dwarf mice are similar to those of their wild-type controls and hence susceptible to MPTP-induced toxicity.     

Epilepsy and electromagnetic fields: effects of simulated atmospherics and 100-Hz magnetic fields on audiogenic seizure in rats

In order to study the possible association between epileptic seizures and natural electromagnetic fields, 32 female audiogenic seizure (AGS)-susceptible rats were exposed to simulated 10 kHz and 28 kHz atmospherics and to a sinusoidally oscillating magnetic field with a frequency of 100 Hz and field strength of 1 A/m. After the electromagnetic exposure, seizures were induced in the rats with a sound stimulus. The severity of the seizure was determined on an ordinal scale, the audiogenic response score (ARS). The time from the beginning of the sound stimulus to the onset of the seizure (seizure latency) and the duration of the convulsion was measured. No differences from the control experiments were found in the experiments with simulated atmospherics, but the 100 Hz magnetic field increased the seizure latency by about 13% (P<0.02). The results do not support the hypothesis that natural atmospheric electromagnetic signals could affect the onset of epileptic seizures, but they suggest that AGS-susceptible rats may be a useful model for studying the biological effects of electromagnetic fields.     

Inferior colliculus neuronal response abnormalities in genetically epilepsy-prone rats: evidence for a deficit of inhibition

The genetically epilepsy-prone rat (GEPR) is abnormally susceptible to induction of seizures by acoustic stimulation. The inferior colliculus (IC) is critically important to audiogenic seizure susceptibility. The GEPR is more susceptible to induction of audiogenic seizures at 12 kHz than at other pure tone frequencies. IC neurons in the GEPR exhibit significantly elevated response thresholds and broader tuning characteristics than normal. These findings along with previous neurophysiological and anatomical data suggest that a hearing deficit occurs in the GEPR. IC neurons in the GEPR exhibit a significantly elevated incidence of a response pattern with a peak of activity at the beginning and end of the stimulus, the onset-offset response. This response pattern occurs at 12 kHz and at characteristic frequency with high stimulus intensities and may represent an afterdischarge phenomenon. The onset-offset pattern may be a manifestation of central mechanisms developed to compensate for reduced peripheral auditory input that appears to be involved in the hearing deficit of the GEPR. Such compensatory mechanisms may involve alterations of the actions of neurotransmitters of the brain-stem auditory nuclei. GABA is implicated as an inhibitory transmitter in the IC. Iontophoretic application of GABA or a benzodiazepine produces significantly less inhibition of IC neurons of the GEPR than of the normal rat. Endogenous sound-induced (binaural) inhibition which is suggested to be GABA-mediated is also significantly reduced in IC neurons of the GEPR. Iontophoresis of the GABAA antagonist, bicuculline, often converts normal response patterns in the IC to onset-offset responses seen with high incidence in GEPR IC neurons, suggesting that the decreased effectiveness of GABA may lead to the onset-offset prevalence. This reduced effectiveness of inhibition may be unable to compensate for the rise in the putative excitatory transmitter, aspartate, in IC during high intensity acoustic stimulation in the GEPR. These altered transmitter actions may be important mechanisms subserving initiation of audiogenic seizures in the genetically epilepsy-prone rat.     

Effects of thermal preconditioning on convulsive activity in rats with inheritable form of audiogenic epilepsy

Effects of thermal preconditioning universal recognized method of increase in concentration of inducible Heat shock protein 70 kDa (Hsp70i) on characteristics of convulsive activity in Krushinskii-Molodkina (KM) rats with inheritable audiogenic epilepsy were studied. For the first time, it was found that short-term thermal preconditioning (41 degrees C during 5 minutes) increased duration of the latency of audiogenic seizure onset. Thermal preconditioning resulted in an increase in concentration of Hsp70i in amygdale, hypothalamus, midbrain; the uttermost increase was observed in hippocampus and inferior colliculus: the brain areas responsible for initiation of audiogenic seizures. A coincidence was found in the term of increase in concentration of Hsp70i and the latency of seizure onset (on day 4 after thermal preconditioning). Results of this research confirm the proposition that inducible Hsp70i is capable of taking part in the processes of seizure development in rats with inheritable form of audiogenic epilepsy.