Adrenalectomy: protection from kindled convulsion induced amnesia in rats

Stress and epilepsy: multiple models, multiple outcomes

Human studies show a link between stress and epilepsy, with stress causing an increase in seizure frequency and severity in patients with epilepsy. Many different animal model systems have been used to better understand this connection and the possible mechanisms involved. This review highlights the results of such studies relating stress and seizure susceptibility, with a focus on the hypothalamic-pituitary-adrenal axis and its relationship to seizure generation. The effects of hypothalamic-pituitary-adrenal axis mediators, acute stress, chronic stress, and early life stress on the seizure phenotype are summarized. Results suggest that stress has both anticonvulsive and proconvulsive properties, depending on the animal strain and the stress/seizure induction paradigm used. Attempts to interpret the stress-epilepsy literature must take these variables into account. The growing availability of genetically modified mice that carry either human epilepsy mutations or mutations in stress pathway genes now provide the opportunity to examine the relationship between stress and epilepsy more directly.

Brain electrical stimulation: kindling and memory aspects

After short introduction in which mile-stones of brain electrical stimulation are mentioned, author discusses kindling as a model of epilepsy and learning. The plastic nature of these two neuronal processes is discussed from the point of view: 1. similarities of these two processes and 2. relation between epileptic discharges (seizures) and learning (memory). The lack of quantitative analysis of afterdischarge duration and its effect on retention is emphasized. Author presents his own study of relation between performance of formed motor avoidance conditioned reflex (CR) and epileptic spontaneous spike activity in hippocampi and duration of afterdischarges (AD) in hippocampi and amygdala in hippocampal kindling in cats. It was shown that spontaneous hippocampal spikes, dissipated over a time, have no effect on performance or retention of the CR. However, there is clear relation between duration of AD and retention of the CR. When duration of the AD was to 15 seconds, correct CRs were obtained in 75% and in 25% the result was negative CR. However, when duration of the AD was longer, the CS presentation between 16-30 sec. resulted in 75% of negative CR and 25% of positive CRs. When the CS was presented during ADs which were longer than 30 sec. almost in all cases the CR was negative, however, in a few instances still possible. Complex effect of brain stimulation are discussed and value of weak stimulation like in kindling technique is emphasized.

Working and Reference Memory in Seizure-Prone and Seizure-Resistant Rats: Impact of Amygdala Kindling

In rat selectively bred for different amygdala kindling rates (Fast vs. Slow), comorbid differences in learning were detected. Here, performance was tested in a delayed alternation task before, during, and after kindling. Although similar reference memory was evident, Fast rats showed working memory deficits with increasing delays between information and choice trials. Further, seizures shortly before learning disrupted both reference and working memory in Fast, but not Slow, rats. Weeks after kindling, progressive delays further disrupted Fast rats, but only longer delays disrupted Slow rats. Clearly relevant to individual differences in human epilepsy, a temporal lobe, seizure-prone genetic background in rats provides poorer original learning and easier disruption of new learning by recent and past seizures than a seizure-resistant background.

An experimental test of the relationship between temporal variability of feeding opportunities and baseline levels of corticosterone in a shorebird

In this study, we tested the hypothesis that baseline corticosterone levels increase with a change from constant to variable feeding schedules. Captive red knots, Calidris canutus, were presented with food that was either available during the same time each day (constant) or starting at variable times during the day. Food intake rates, frequency of aggressive interactions, and baseline levels of corticosterone were measured. In the majority of cases, red knots showed higher plasma corticosterone concentrations during feeding schedules that were irregular than when food was available at consistent times. These findings are supported by a previous study that showed that red knots take a long time to adjust to the newly offered, predictable conditions of their aviary environment. The frequency of conflicts in the different groups and (size-corrected) body mass were not correlated with average corticosterone level. The results are examined in the light of literature showing that increases in corticosterone in response to acute, unpredictable events mediate behavioral responses such as increased explorative behavior and memory. For red knots that have to find their food on the temperate-zone mudflats in Western Europe, an increased circulating corticosterone level may be adaptive during periods when the patchily distribution of buried bivalves and the burying behavior of such prey presents them with a variable and unpredictable food supply.

Amnesia induced by stimulation of the amygdala is attenuated by hexamethonium

Bilateral subseizure stimulation of the amygdala given immediately following training in an inhibitory avoidance task produced retrograde amnesia. Hexamethonium (3.0 and 10.0 mg/kg), a peripherally acting nicotinic cholinergic antagonist, attenuated the retention deficits induced by amygdala stimulation if the drug was given 30 min prior to, but not immediately following training. Hexamethonium had no effect in normal unoperated animals, but did produce a retention deficit in operated control (nonstimulated) animals if it was given immediately following training (3.0 and 10.0 mg/kg). The results suggest that memory deficits induced by electrical stimulation of the amygdala are associated with, or perhaps mediated in some way by peripheral autonomic function.

Effects of generalized convulsive seizures on corticotropin-releasing factor neuronal systems

Most stressors generate a set of endocrine and neural adaptations that form a stress response. The corticotropin-releasing factor neurons of the paraventricular nucleus of hypothalamus integrate endocrine and neural inputs, and cause a cascade of events with resultant increased levels of pituitary adrenocorticotropic hormone and adrenal hormones. Although activation of the hypothalamic-pituitary-adrenal axis is associated with a large variety of stressors, the effects of seizures on hypothalamic corticotropin-releasing factor neurons are essentially unknown. The goal of the present study was to elucidate the effects of generalized convulsive seizures on distinct and separate corticotropin-releasing factor cell populations in brain. Seizure-activated neurons were identified immunocytochemically through their expression of the Fos protein. Seizures were induced by intraperitoneal injection of kainic acid. In the paraventricular nucleus, the vast majority of corticotropin-releasing factor-like parvocellular neurons also expressed Fos-like protein following seizure elicitation. This response was specific to corticotropin-releasing factor neurons of the paraventricular nucleus, as corticotropin-releasing factor neurons in central nucleus of the amygdala or bed nucleus of the stria terminalis did not simultaneously localize Fos following seizures.

Novelty-related rapid locomotor effects of corticosterone in rats

Glucocorticoids modulate brain function and behaviour through different mechanisms. Although classical effects are mediated through intracellular receptors that modulate gene transcription, recent evidence supports the existence of rapid, nongenomic steroid effects through the neuronal membrane. In this study, we explored possible rapid behavioural effects of corticosterone in the rat, which could provide a model to characterize further the mechanisms involved in rapid corticosteroid nongenomic actions. We found that a corticosterone injection, at doses (2.5 or 5 mg/kg) that mimic plasma concentrations produced by substantial stress, rapidly increases (within 7.5 min of its systemic administration) the locomotor response displayed by rats in a novel environment (activity cage). A lower dose of 1 mg/kg failed to induce this effect. In addition, corticosterone failed to increase locomotion when administered to rats that had been previously exposed to the activity cage. Corticosterone-induced increased locomotion in a novelty situation was not counteracted by either the intracerebroventricular administration of the protein synthesis inhibitor cycloheximide, or by the intracerebroventricular administration of specific antagonists for each type of intracellular corticosteroid receptor, i.e. RU28318, a mineralocorticoid receptor antagonist and RU38486, a glucocorticoid receptor antagonist. Further studies supported the viability of the receptor antagonists to display an anti-corticosteroid action interfering, as previously reported, with the behavioural &winning test. Therefore, the rapid actions of corticosterone in locomotor activity described here, which appear to be nongenomic, might provide a model for future research on the elucidation of the mechanisms involved in steroid-membrane interactions.

Juvenile desipramine reduces adult sensitivity to imipramine in two behavioral tests

The behavioral effects of adult imipramine administration were examined in female rats treated with desipramine as juveniles (JDES), treated with saline as juveniles (JSAL), and untreated as juveniles (JUNT). In the forced swimming test, the juvenile groups displayed similar behavioral effects of imipramine when administered short term following a pretest forced swimming exposure. Similar effects of imipramine were observed when administered long term prior to the only test exposure. When rats were not given a pretest forced swimming test exposure, short-term imipramine had no effect on JDES rats but did influence JSAL and JUNT rats. In the open-field test, short- and long-term imipramine treatment affected the behavior of JUNT and JSAL rats. Short-term imipramine treatment influenced open-field behavior of JDES animals, but long-term imipramine treatment had no effect. These results suggest that JDES treatment may permanently alter the neural mechanism underlying the behavioral effects of antidepressant treatment.

Memory modulation with peripherally acting cholinergic drugs

Physostigmine (PHYSO), in doses as low as 0.003 mg/kg IP, antagonized scopolamine (SCOP, 3 mg/kg) induced amnesia of step-through passive avoidance in mice. The peripherally acting acetylcholinesterase (AChE) inhibitor neostigmine (NEO) was also found to reliably, though less strongly, antagonize the SCOP induced amnesia at a dose of 0.03 mg/kg. The NEO antagonism of the SCOP amnesia could be reversed with SCOP (0.3, 1, and 3 mg/kg) and mecamylamine (MECA, 1, 3, and 10 mg/kg), muscarinic and nicotinic antagonists, respectively, which are active both peripherally and centrally, as well as with M-SCOP (0.3 and 1 mg/kg) and hexamethonium (HEX, 1 and 3 mg/kg), muscarinic and nicotinic antagonists, respectively, which are active only in the periphery. In contrast to the ability of these four compounds to attenuate the SCOP amnesia, only the centrally acting compounds SCOP (3 mg/kg) and MECA (10 mg/kg) induced an amnesia when administered alone. These findings suggest that the induction of amnesia of passive avoidance involves central cholinergic systems, whereas the NEO, and possibly PHYSO, reversal of the SCOP induced amnesia is mediated peripherally by both muscarinic and nicotinic receptors. It is hypothesized that the release of adrenal catecholamines, the influence of which on memory processes is well known, and secondarily glucose, may be responsible for the NEO antagonism of the SCOP amnesia.

Central action of adrenal steroids during stress and adaptation

Corticosteroids interact with receptors in the central nervous system. These receptors display heterogeneity and can be distinguished as corticosterone- and aldosterone-binding mineralocorticoid receptors and dexamethasone-binding glucocorticoid receptors. Ligand specificity of mineralocorticoid receptors for either corticosterone or aldosterone seems to be determined by co-localized transcortin and the enzyme, 11 beta-hydroxysteroid dehydrogenase. Aldosterone-selective mineralocorticoid receptors appear to be present in the circumventricular organs and the AV3V region of the hypothalamus and mediate behavior that is driven by salt appetite. Highest concentrations of mineralocorticoid receptors are found in neurons of the hippocampus. These limbic mineralocorticoid receptor sites mediate tonic influences of corticosterone on brain processes. Glucocorticoid receptors bind corticosterone with a tenfold lower affinity than do mineralocorticoid receptors, and are widely distributed in neuronal and glial cells of the brain. Glucocorticoid receptors are involved in the termination of the stress response (negative feedback). Studies involving measurement of glucocorticoid receptor mRNA and binding sites have revealed that glucocorticoid receptors are subject to autoregulation. After ADX, glucocorticoid receptor concentration increases, but is reduced after chronic stress, chronic administration of glucocorticoids, and at senescence. A diminished glucocorticoid receptor concentration may compromise the negative feedback action exerted by glucocorticoids after stress. After ADX, mineralocorticoid receptor binding is acutely up-regulated and reaches its maximum between 7 and 24 hours post-ADX. Mineralocorticoid receptor mRNA level shows a transient increase following ADX. Long-term ADX has no effect on the mineralocorticoid receptor concentration, but, interestingly, chronic dexamethasone treatment results in an up-regulation of mineralocorticoid receptors. Mineralocorticoid receptor level is decreased at senescence, but this age-related decrement can be reversed by chronic treatment with the ACTH4-9 analog, ORG 2766. Functionally, mineralocorticoid receptors and glucocorticoid receptors are involved in different aspects of the organization of the stress response, and in conjunction they control the stress responsiveness of the animal.

Adrenalectomy-induced memory deficits: role of plasma glucose levels

Circulating glucose levels regulate memory storage under several conditions. This study examined the contribution of blood glucose levels to the transient memory impairment seen in adrenalectomized rats. Inhibitory (passive) avoidance retention performance, blood glucose levels, and glycemic responses to footshock were tested 1, 2, and 8 days after adrenalectomy. Adrenalectomized animals demonstrated a transient inhibitory avoidance deficit 1 and 2 days after surgery which recovered by 8 days. The adrenalectomy-induced memory deficit was accompanied by decreased resting blood glucose levels. In animals tested 2 days after adrenalectomy, this decrease in baseline blood glucose levels was exacerbated by further reductions, rather than the normal increases, in circulating glucose levels after training. The magnitude of blood glucose increases after glucose injection was decreased in adrenalectomized animals tested 2 days after surgery. Posttraining glucose injections restored the retention performance of animals trained 2 days after adrenalectomy to that of sham-operated animals. These findings suggest that abnormalities in blood glucose regulation may contribute, in part, to the transient memory impairment seen after adrenalectomy. Additionally, the results further implicate blood glucose in the regulation of CNS information processing systems.

Adrenocortical hormone regulation of nicotine sensitivity in mice

The possibility that nicotine-induced corticosterone (CCS) release regulates nicotine sensitivity was investigated in female mice of the C3H strain. Adrenalectomy (ADX) resulted in an increase in nicotine sensitivity as measured in a number of physiological and behavioral tests. In ADX animals, chronic CCS (100 micrograms/ml) administered in the drinking solution normalized nicotine sensitivity. Dexamethasone (DEX), a potent synthetic glucocorticoid which interacts with a distinct population of CNS steroid receptors, did not reverse the effects of ADX. Unoperated animals administered CCS (200 micrograms/ml) were protected from the effects of nicotine for several test battery parameters. ADX had no effect on the number of brain nicotinic cholinergic receptors and also did not alter nicotine metabolism. These data support the hypothesis that CCS secretion modulates nicotine sensitivity in the mouse; however, the mechanisms by which this regulation occurs are unknown.

Effects of corticosterone on shaking and seizure behavior induced by deep prepyriform cortex kindling

The influence of adrenocorticosteroids on seizures and wet dog shakes (WDS) induced by deep prepyriform cortex kindling was studied by bilateral adrenalectomy and corticosterone replacement. The rate of kindling, latency to the onset and duration of motor seizures were not significantly affected by adrenalectomy or corticosterone treatment. However, the number of WDS observed after stage 5 seizures was reduced in adrenalectomized animals and it was not restored until 3 h following corticosterone replacement. This delay in onset of action suggests that the effects of adrenocorticosteroids and/or ACTH on WDS may be mediated by an indirect mechanism.

Plasma ACTH and corticosterone responses to limbic kindling in the rat

Changes in plasma ACTH and corticosterone concentrations were measured in individual cannulated rats at stages 1 and 5 of limbic kindling induced by electrical stimulation of the basolateral amygdala or the dorsal hippocampus. At both stages, a stimulation of either structure produced swift surges, first of ACTH and then of corticosterone. At stage 5 of hippocampal stimulation, ACTH baseline concentrations were four times higher than in the controls. The results are discussed in relation to the central control of the adrenocorticotropic system and to the neuroendocrine correlates of the kindling process.

Peripheral epinephrine modulates the effects of post-training amygdala stimulation on memory

The present study investigated the role of adrenal epinephrine in the memory modulatory effects of post-training amygdala stimulation. Adrenal demedullated (ADMX) or sham demedullated (SHAM) rats received electrical stimulation of the amygdala immediately after training on inhibitory and active avoidance tasks. With both tasks, the stimulation impaired retention only in the rats with intact adrenal medullae: the retention performance of the ADMX in the rats with intact adrenal medullae: the retention performance of the ADMX rats given post-training stimulation was better than that of the unstimulated ADMX group with implanted electrodes. However, ADMX rats given post-training epinephrine (1.0 mg/kg, s.c.) immediately before the amygdala stimulation had retention deficits comparable to those of the SHAM group given amygdala stimulation. If epinephrine was administered a short time after rather than before the post-training amygdala stimulation, retention of the ADMX animals was not impaired. The findings are interpreted as indicating that circulating epinephrine present at the time of amygdala stimulation modulates the effects of amygdala stimulation on memory.

Depletion of adrenal catecholamines alters the amnestic effect of amygdala stimulation

Amygdala stimulation produces a robust retrograde amnesia which appears to be related to peripheral hormonal responses to stress. This present study investigated the effects of electrical stimulation of the amygdala delivered immediately after inhibitory and active avoidance training to rats depleted of adrenal catecholamines or sham adrenal operated rats. Comparable findings were obtained with the two training tasks: amygdala stimulation impaired retention of sham adrenal operated rats but it enhanced retention of rats depleted of adrenal catecholamines. These findings suggest that adrenal catecholamines released during a training situation modulate the effects of amygdala stimulation on memory.

State-dependent learning following electrical stimulation of the hippocampus: intact and split-brain rats

In experiment 1, electrical stimulation of the posterior hippocampus was shown to produce state-dependent learning (SDL) for a step-out inhibitory avoidance task in rats. Stimulation sites in either the right or left hippocampus were equally effective in producing this effect. Similarly, the presence or absence of afterdischarge (AD) following the stimulation did not differentially affect performance on the task. In experiment 2, forebrain bisection ameliorated the behavioral deficits in the animals receiving stimulation before testing but not before training (N/S group), while those stimulated before training but not before testing (S/N group) remained impaired; thus, providing a demonstration of asymmetrical SDL. Variations in extent of the commissurotomy differentially affected the laterality of the afterdischarge but not the performance in the SDL task. Speculation as to the mechanisms of this SDL effect was presented.

Hippocampal kindling: corticosterone modulation of induced seizures

The effect of adrenalectomy (ADX) and corticosterone replacement was studied on seizures induced by hippocampal kindling. A complex series of changes occurred in after-discharge (AD) and behavioural depression (BD) during the immediate hours after ADX, culminating at day 1 in markedly decreased AD and BD, which returned to normal over the next several days. These changes were normalized after replacement of the ADX group with low doses of corticosterone. It is concluded that the expression and maintenance of hippocampal kindled seizures is under short-term control of corticosterone.

Inhibitory avoidance deficit following short-term adrenalectomy in the rat: the role of adrenal catecholamines

Impaired retention of an inhibitory avoidance response was observed in rats subjected to adrenalectomy (ADX) up to 120 hr before the single learning trial. Corticosterone substitution failed to normalize this behavioral deficit. Rats ADX 240 hr prior to the learning trial showed a normalized behavior. Adrenomedullectomy (ADXM) 48 or 240 hr before learning caused a similar impairment as in short-term ADX rats. The 240-hr ADX rats subjected to corticosterone substitution showed the same behavioral deficit as short-term ADX rats or ADXM ones. Immediate postlearning subcutaneous injection of adrenaline in a dose range of 0.005-5.0 micrograms/kg or of noradrenaline (0.005-0.5 microgram/kg) to 48-hr ADX rats resulted in a dose-related improvement of later retention behavior. Higher doses of catecholamines were less or ineffective. Postlearning treatment of 48-hr ADXM rats with adrenaline (0.5-500 micrograms/kg) caused a similar pattern of behavioral changes. It is concluded that adrenal catecholamines play an important role in the modulation of consolidation of memory. In addition, the high circulating ACTH levels that follow long-term ADX may correct for the behaviorial deficit induced by the absence of adrenomedullary catecholamines.

Antagonistic effects of aldosterone on corticosterone-mediated changes in exploratory behavior of adrenalectomized rats

The effect of aldosterone administration on exploratory activity of chronic adrenalectomized (10 days) male rats was investigated. Aldosterone (30 micrograms/100 g body wt sc) administered 1 hr or 30 min prior to the behavioral test failed to normalize disturbed exploratory activity of adrenalectomized rats, in contrast to the restoration observed after corticosterone, the naturally occurring glucocorticoid of the rat. Administration of the mineralocorticoid 30 min prior to corticosterone prevented the normalization of the behavioral response by the latter steroid. Administration of the same dose of aldosterone 30 min prior to a tracer amount of [3H]corticosterone effectively blocked cell nuclear uptake of radioactive-labeled hormone in the hippocampus. The specific action of corticosterone on exploratory behavior corresponds with the stringent specificity of the neuronal hippocampal corticosterone receptor system. Mineralocorticoid receptors do not seem to be involved in effects on this behavior. The antagonistic action of aldosterone is probably exerted by competitive binding to the corticosterone receptor.

Hormonal influences on seizure kindling: the effects of post-stimulation ACTH or cortisone injections

Repeated application of brain stimulation can lead to a progressively augmenting electrical and behavioral response-- a phenomenon termed seizure kindling. In this experiment, stimulation was delivered once per day, and was followed by peripheral (intraperitoneal) administration of ACTH or cortisone. An intermediate or a high dose of either hormone (0.3 IU or 3.0 IU of ACTH/animal, 10 mg or 25 mg cortisone/animal) delayed the completion of kindling if administered shortly after each kindling stimulation. Lower doses (0.03 IU of ACTH or 2 mg of cortisone) had no significant effects. The high dose of ACTH or cortisone was no longer effective if administration was delayed more than 4 h after stimulation. Peripherally administered ACTH and cortisone can influence processes initiated by the brain stimulation which presumably underlie the augmentation of response to successive stimulations. This time-limited action is analogous to the effects of these hormones on memory consolidation.

Effects of focal vs generalized kindled convulsions from anterior neocortex or amygdala on CER acquisition in rats

Kindling of the anterior neocortex (AC) was shown to produce a brief focal motor seizure, characterized by a clonic-tonic-clonic response of the forelimbs with the animal in a prone posture. These same brief seizures, as previously reported, did not produce retrograde amnesia in a CER paradigm. With repeated evocations, over several days, the AC convulsions exhibited a dramatic increase of the second clonic phase (generalized) and came to appear similar to amygdala kindled convulsions. These generalized AC convulsions, like briefly kindled amygdala convulsions, produced good retrograde amnesia for a CER. With extensive amygdala kindling prior to CER training, a severe CER acquisition deficit was observed. These latter as well as other data suggest that protracted amygdala kindling produces a subsequent reduced ability to acquire fear motivated responses.