Phenotypic expression of the systemic toxicity of cocaine in genetically epilepsy-prone rats.

The purpose of the present investigation was to determine whether the sensitivity to systemic toxic effects of cocaine is altered in genetically epilepsy-prone rats (GEPRs). Moderate seizure (GEPR-3) and severe seizure (GEPR-9) rats, and the control strain, Sprague-Dawley rats, 10 weeks of age, were lightly anesthetized with halothane and nitrous oxide. Following surgical preparation and stabilization, the animals were given a constant intravenous infusion of cocaine (4 mg/kg per min) until death. Blood pressure, ECG, and EEG were monitored continuously throughout the experiment. Cocaine doses required to produce seizures (i.e., epileptiform activity on the EEG) were not significantly different between GEPRs and control rats (16.8+/-0.6 mg/kg in GEPR-3, 18.7+/-0.7 mg/kg in GEPR-9, and 14.7+/-1.3 mg/kg in Sprague-Dawley). Seizure duration, amplitude and the number of epileptiform bursts were also similar among the three strains. Additionally, there was no significant difference in cocaine doses that produced arrhythmias and cardiac asystole between GEPRs and control. The results indicate that genetically epilepsy-prone rats do not exhibit altered sensitivity to cocaine-induced seizures despite the marked susceptibility to sound-evoked seizures. Local anesthetic-induced seizures and acoustically-evoked seizures apparently have different underlying mechanisms.

Two genetically selected strains of rats exhibit hypersensitivity or resistance to cocaine-induced fatal arrhythmias.

We identified for the first time two genetically selected strains of rats that differ markedly in sensitivity to cocaine-induced life-threatening cardiac arrhythmias and arrest. The two strains of rats, designated as Fast and Slow, were bred for sensitivity (Fast) or resistance (Slow) to electrically kindled seizures. Studies were performed on halothane-anesthetized, mechanically ventilated rats. Animals were given cocaine (3 or 4 mg/kg/min i.v.) until they died. Arrhythmias (atrioventricular conduction block) developed at much lower cumulative cocaine doses in Slow-kindling rats than in Fast-kindling rats (15 +/- 1 versus 42 +/- 3 mg/kg, p <.01). The lethal cocaine dose (the dose that caused cardiac arrest) was also markedly lower in Slow than in Fast strains (32 +/- 2 versus 62 +/- 6 mg/kg, p <.01). These differences between the two strains were not significantly altered by pretreatment of animals with either ganglionic blockers, hexamethonium (20 mg/kg i.v.) or chlorisondamine (5 mg/kg i.v.), or a nonselective beta adrenergic receptor blocker, propranolol (1 mg/kg i.v.). A nonselective alpha adrenergic receptor blocker, phentolamine (10 mg/kg i.v.), however, abolished the differences between the Fast and Slow strains in the doses of cocaine required to produced atrioventricular conduction block and cardiac arrest. The results provide the first evidence of genetically determined susceptibility or resistance to cocaine-induced cardiotoxicity. There appears to be a genetically determined difference in the alpha adrenergic receptor system between the two strains that is responsible for the differential sensitivity to cocaine-induced arrhythmias and cardiac arrest.

Alterations in brain and pituitary beta-endorphin content in genetically epilepsy-prone rats.

We measured beta-endorphin concentrations in the anterior and neurointermediate lobes of the pituitary gland and in microdissected brain regions of moderate-seizure genetically epilepsy-prone rats (GEPR-3), severe-seizure GEPR-9s and Sprague-Dawley non-epileptic control rats. Plasma concentrations of beta-endorphin and beta-melanocyte-stimulating hormone (alpha-MSH) were also measured as indicators of pituitary POMC-peptide secretion. Concentrations of beta-endorphin in the anterior lobe of GEPR-3s were 53% higher compared to controls and 57% higher compared to GEPR-9s. There were no differences in neurointermediate lobe beta-endorphin concentrations between control and either GEPR strain. Plasma beta-endorphin concentrations were significantly lower in GEPR-9s than controls. Plasma levels of alpha-MSH did not differ between control and GEPRs. In the hypothalamus of GEPR-9s beta-endorphin concentrations in the arcuate nucleus were significantly greater than in GEPR-3s. Concentrations of beta-endorphin in the central amygdala of GEPR-9s were two- to threefold greater than in control or GEPR-3s. Beta-Endorphin concentrations in the central gray of GEPR-3s were 58% lower than control or GEPR-9s. These data suggest that anterior lobe beta-endorphin secretion is reduced in GEPR-9s. Furthermore, brain endorphinergic pathways appear to be differentially altered in GEPR-3s and GEPR-9s. Alterations in pituitary beta-endorphin secretion and brain endorphinergic systems may contribute to seizure susceptibility in GEPRs and to differences in seizure severity between GEPR-3s and GEPR-9s.

Alterations in mRNA expression of systems that regulate neurotransmitter synaptic content in seizure-naive genetically epilepsy-prone rat (GEPR): transporter proteins and rate-limiting synthesizing enzymes for norepinephrine, dopamine and serotonin.

Two models of genetically epilepsy-prone rat (GEPR) exist, the GEPR-3 and GEPR-9, GEPR-3 and GEPR-9 share a deficiency in presynaptic norepinephrine (NE) and serotonin (5HT) content in specific regions of the central nervous system (CNS). The presynaptic content of dopamine (DA) does not appear to be altered in either adult GEPR strain compared to Sprague-Dawley (SD) rats, the strain from which the GEPR was derived. Presynaptic content of monoamine neurotransmitters, such as NE, 5HT and DA, are maintained by several regulatory proteins which include: synthesis, re-uptake, release, degradation and vesicular transport. To further characterize the monoamine deficiency observed in the GEPR, the mRNA level of the rate limiting enzymes for the synthesis of NE, 5HT and DA and each of the neurotransporter proteins were measured in seizure-naive GEPR-3, GEPR-9 and SD rats. In the locus coeruleus (LC), the major noradrenergic locus, tyrosine hydroxylase (TH) mRNA level was significantly reduced only in GEPR-9 animals compared to SD rats and GEPR-3, while NE transporter (NET) mRNA was significantly elevated in GEPR-3 compared to SD rats and GEPR-9. TH and DA transporter (DAT) mRNA was measured in the dopaminergic neurons of the substantia nigra pars compacta (SNpc), ventral tegmental area (VTA) and zona incerta (ZI), DAT mRNA level was significantly reduced in all dopaminergic neurons in the GEPR-3 compared to SD rats and GEPR-9, while TH mRNA level was significantly elevated in the SNpc/VTA equally in GEPR-3 and GEPR-9 compared to SD rats. In the ZI, TH mRNA level was significantly reduced in GEPR-3 compared to SD rats and GEPR-9. In the dorsal raphe (DR), a major serotonergic locus, tryptophan hydroxylase (TRH) mRNA level was not significantly different from SD in either strain of GEPR; however, 5HT transporter (SERT) mRNA level was significantly reduced in GEPR-9 in the dorsal and lateral regions of the DR compared in SD rats and GEPR-3. These data indicate that two of the regulatory systems that maintain NE, 5HT and DA content are altered in a differential manner in seizure-naive GEPR-3 compared to seizure-naive GEPR-9, with GEPR-3 showing more alterations in dopaminergic neurons. It is uncertain at the present time how these alterations in mRNA level relate to the enhanced seizure susceptibility of these animals. It was apparent that a straightforward correlation between neurotransmitter loss to transcriptional changes in synthesizing enzymes mRNA or to re-uptake protein mRNA was not observed in noradrenergic and serotonergic neurons. Therefore, the decrease in presynaptic NE and 5HT tissue content in these animals may be due to posttranscriptional modification. In contrast, presynaptic DA tissue content which was unaltered in both strains of GEPR, shows an alteration in TH and DAT mRNA level compared to SD rats in all dopaminergic neurons examined. This indicates a possible involvement of DA in regulating the seizure susceptibility of these animals.

Effect of reserpine pretreatment on avian erythrocyte carbonic anhydrase activation by isoproterenol.

We studied the action of beta-adrenergic agonists on Japanese quail erythrocyte carbonic anhydrase (CA) in vitro. Earlier we had reported that epinephrine increased CA activity by 14%; the present study focused on an attempt to increase the size of this response. Washed erythrocytes from reserpine-treated (1 mg/kg daily i.m. for 3 days) and control birds were incubated for 40 min in the presence of isoproterenol 10(-6) mol/l. The activity of CA expressed as Wilbur-Anderson units/mg hemoglobin was increased by as much as 42% in reserpine-treated birds over the control depending on the conditions. Addition of 10(-5) mol/l of the beta-adrenergic antagonist propranolol inhibited the isoproterenol-induced effect in nonreserpinized birds. We conclude that pretreatment with reserpine, which was accompanied by a fall in plasma catecholamine levels, particularly epinephrine levels, enhanced the activation of CA by isoproterenol.

Decrease in hippocampal [3H]vinylidene kainic acid binding in genetically epilepsy-prone rats.

Specific [3H]vinylidene kainic acid binding to the kainate-sensitive subtype of glutamate receptor was studied in brain of 31-day-old non-epileptic Sprague-Dawley control and two colonies of genetically epilepsy-prone rats using in vitro autoradiographic techniques. At 37.5 nM [3H]vinylidene kainic acid, specific [3H]vinylidene kainic acid binding was reduced significantly by 18 and 22% in dorsal and ventral hippocampal formation stratum lucidum of 31-day-old genetically epilepsy-prone-9 rats compared with non-epileptic controls. Hippocampal [3H]vinylidene kainic acid binding was reduced in genetically epilepsy-prone-3 rats by 15 and 18%, but these reductions were not statistically significant. Saturation of [3H]vinylidene kainic acid binding studies indicated that the total number of ventral hippocampal [3H]vinylidene kainic acid binding sites was decreased by 21% in genetically epilepsy-prone-3 rats and 28% in genetically epilepsy-prone-9 rats. The reduction in ventral hippocampal [3H]vinylidene kainic acid binding in genetically epilepsy-prone rats resembles the reduction in ventral hippocampal [3H]vinylidene kainic acid binding sites observed in perinatal hypothyroid rats. As genetically epilepsy-prone rats are hypothyroid during the neonatal period, the reduction in hippocampal [3H]vinylidene kainic acid binding in the genetically epilepsy-prone rats may be a consequence of a hypothyroid-induced defect in the development or maturation of the hippocampal mossy fiber projection in genetically epilepsy-prone rats. An alternative hypothesis is that the putative occurrence of spontaneous limbic seizures in genetically epilepsy-prone rats may lead secondarily to a reduction in hippocampal [3H]vinylidene kainic acid binding sites.

Ontogeny of sound-induced seizures in the genetically epilepsy-prone rat.

Seizure responsiveness of the adult genetically epilepsy-prone rat (GEPR) is well documented. Much less is known about the ontogeny to seizure activity in the GEPR. In the present study, members of the moderate seizure (GEPR-3) and severe seizure (GEPR-9) colonies were tested for susceptibility to sound-induced seizures at 11 different ages ranging from 13 to 45 days post partum. Running episodes first appeared in GEPR-3s at 15 days post partum. Clonic seizures first appeared in GEPR-3s and GEPR-9s at 15 and 16 days post partum, respectively. Seizure incidence reached 100% by post partum day 21 in both colonies. GEPR-3s exhibited a 100% incidence of their characteristic clonic seizure at day 21. GEPR-9s exhibited a 77.3% incidence of clonic seizure and a 22.7% incidence of their adult characteristic tonic seizure at day 21. Tonic seizures first appeared in GEPR-9s at day 18 and increased in incidence over time reaching 100% by day 45. Two unexpected findings occurred in GEPR-3s. First, secondary rearing seizures were detected in all GEPR-3s exhibiting clonic seizures between day 16 and 21. Second, GEPR-3s exhibited a transient susceptibility between 19 and 27 days post partum to the more severe tonic seizures characteristic of adult GEPR-9s. Peak incidence of tonic seizures in GEPR-3s was 70%, occurring at day 23. The adult GEPR-3 pattern of 100% incidence of clonic seizures was restored by day 45.

Audiogenic convulsions in moderate seizure genetically epilepsy-prone rats (GEPR-3s).

The moderate seizure genetically epilepsy-prone rat (GEPR-3) typically exhibits a generalized clonic convulsion upon acoustical stimulation. The purpose of this report is to document sex-specific distinctions in the seizure characteristics as well as the effect of prior seizure experience on sensitivity to acoustically induced seizures in members of the GEPR-3 colony. Convulsive behavior was evaluated in approximately 3300 GEPR-3s. Each of these animals was stimulated with sound 3 times at weekly intervals. Audiogenic response score (ARS), latency to the onset of wild running and latency to convulsion were recorded for each animal in each of 3 tests given at 1 week intervals. Statistical analysis revealed that compared to their male littermates, females exhibited significantly shorter latencies to onset of running and convulsion for the last of the 3 weekly tests. Also, in both sexes, a significantly higher incidence of clonic convulsions, an increase in audiogenic response scores and a reduction in latencies to running and convulsion were observed in each succeeding audiogenic stimulation test. The mechanism of this increased seizure facilitation with prior seizure experience may have at least some similarity to that of kindling. The factors responsible for sex-specific distinctions in seizure severity are unknown at the present time.

Neurobiology of seizure predisposition in the genetically epilepsy-prone rat.

Seizure predisposition in the genetically epilepsy-prone rat (GEPR) is innately determined and these animals exhibit consistent and reproducible convulsive patterns. This epilepsy model is made up of 2 independently derived colonies of animals with each exhibiting a characteristic convulsive pattern. In response to a standardized acoustic stimulus, GEPR-3s exhibit moderate or clonic convulsions and GEPR-9s exhibit more severe tonic extensor convulsions. Besides exhibiting convulsions in response to sound stimulation, some GEPRs experience spontaneous and hyperthermic seizures. They are also abnormally sensitive to a number of seizure provoking stimuli that produce seizures in normal animals. The neurochemical basis for the seizure predisposition in GEPRs is increasingly well understood. Abnormalities in central nervous system norepinephrine and serotonin are widespread and may play a prominent role in regulation of seizures in the GEPR. Amino acid neurotransmitter systems are less well defined in the GEPR but abnormalities exist and may be, along with other documented deficiencies, responsible in part for the seizure predisposition that is characteristic of GEPRs.

Sex-specific distinctions in audiogenic convulsions exhibited by severe seizure genetically epilepsy-prone rats (GEPR-9s).

The severe seizure genetically epilepsy-prone rat (GEPR-9) is characterized by a broad-based seizure predisposition and is increasingly recognized as a useful model of epilepsy. When sound stimulated, members of the GEPR-9 colony exhibit complete tonic extensor convulsions. Female GEPR-9s appear to experience a higher frequency of more severe seizures than males when they are sound stimulated. The purpose of this report is to examine and document this observation. Convulsive behavior was evaluated in approximately 4400 GEPR-9s. Each of these animals was sound stimulated 3 times at weekly intervals. Audiogenic response score (ARS), latency to wild running and latency to convulsion were recorded for each animal in each of the 3 tests. For the first 2 weekly tests, females exhibited a significantly higher incidence of complete tonic convulsions, a significantly higher ARS and significantly shorter latencies to wild running and convulsions than did males. The significant differences in latencies persisted through the 3 tests, whereas an increase in the incidence of complete tonic convulsions among males led to a diminution of the differences between males and females in the other parameters. The possible underlying biochemical differences that are responsible for this sex difference in seizure severity are, as yet, unknown.

Elevation of naloxone-sensitive 3H-dihydromorphine binding in hippocampal formation of genetically epilepsy-prone rats.

3H-Dihydromorphine (DHM) binding sites were measured in the brain of non-epileptic control and GEPR rats using in vitro autoradiographic techniques. The number of naloxone-sensitive 3H-DHM binding sites was increased 38-57% in the pyramidal cell layer of ventral hippocampal CA3 and Ca1 of GEPR-3 and GEPR-9 rats compared to non-epileptic controls. No significant differences in 3H-DHM binding were observed in dorsal hippocampal formation, lateral entorhinal cortex, lateral geniculate or cerebellum. The results suggest that an increase in the number of opioid receptors in ventral hippocampus of GEPR rats may be one factor contributing to the enhanced sensitivity of GEPR-9 rats to the proconvulsant effects of morphine.

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.

Responsiveness of genetically epilepsy-prone rats to intracerebroventricular morphine-induced convulsions.

The sensitivity to intracerebroventricular morphine-induced convulsions was determined in members of the severe seizure (GEPR-9) and moderate seizure (GEPR-3) colonies of genetically epilepsy-prone rats as well as in non-epileptic control rats. GEPR-9s were more sensitive to morphine-induced wet-dog shakes, rearing with bilateral forelimb clonus and generalized clonus than controls of GEPR-3s. GEPR-3s were less sensitive to morphine-induced wet-dog shakes and rearing with bilateral forelimb clonus than controls. Both high and extremely low doses of morphine in GEPR-9s elicited tonic extensor convulsions resembling the characteristic sound-induced convulsion of GEPR-9s. The results suggest that opiotergic systems may contribute to the pathophysiology of the seizure-prone condition in GEPR-9s. Further, differences in responsiveness of opiotergic systems in GEPR-3s and GEPR-9s may partially account for differences in seizure severity in the characteristic sound-induced seizures of these two types of GEPRs.

The development of kindled seizures is accelerated in the genetically epilepsy-prone rat.

The kindling phenomenon was examined in genetically epilepsy-prone (GEPR) and non-epileptic control Sprague-Dawley rats. Kindling stimulations were administered three times a day until each rat had exhibited three Class 5 kindled motor seizures. The mean total number of kindling stimulations required for each experimental group to exhibit three motor seizures of each motor seizure class was determined. The results indicated that the early stage of kindling development was accelerated significantly in both the GEPR-3 and GEPR-9 rats, compared to non-epileptic control rats. Later stages of kindling development were accelerated in GEPR-9 but not GEPR-3 rats. Thus a differential acceleration of kindling development was exhibited by GEPR-3 and GEPR-9 rats. The results suggest the possibility that some brain region(s) involved in the early stages of kindling development may be hyperexcitable in both GEPR-3 and GEPR-9 rats. Other brain region(s) involved with the later stages of kindling development may be more excitable in GEPR-9 rats. These putative alterations may, in part, contribute to the seizure prone state of GEPR rats and the differential seizure responses of GEPR-3 and GEPR-9 rats.

The genetically epilepsy-prone rat: an overview of seizure-prone characteristics and responsiveness to anticonvulsant drugs.

The Genetically Epilepsy-Prone Rat (GEPR) is rapidly gaining support as a model of epilepsy. In addition to a marked sensitivity to both sound-induced and hyperthermic seizures, GEPRs exhibit unusual sensitivity to a number of seizure-provoking modalities, including various forms of electrical and chemical stimulation. The existence of a moderate seizure colony (GEPR-3) and a severe seizure colony (GEPR-9) allows pathophysiological studies of seizure susceptibility and severity. The consistency of seizures within each colony allows for comparisons in seizure naive GEPRs and seizure experienced GEPRs. The consistent seizure responses of the GEPR are also ideal for the testing of anticonvulsant drugs. Further, the relative potencies of anticonvulsant drugs between the two colonies of GEPRs predict the clinical efficacies of traditional antiepileptic drugs and may be able to predict novel anticonvulsants.

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.

Angular bundle kindling is accelerated in rats with a genetic predisposition to acoustic stimulus-induced seizures.

Limbic kindling was examined in genetically epilepsy-prone (GEPR) and non-epileptic control rats. The early stage of kindling development was accelerated in both groups of GEPR rats compared to controls. Later stages of kindling were accelerated in GEPR-9 but not GEPR-3 rats. These results indicate that GEPR rats have an enhanced susceptibility to limbic kindling and suggest that limbic brain alterations may contribute to acceleration of the early stage kindling development in GEPR rats.