S. Pretel

APOPTOTIC AND NECROTIC CELL DEATH FOLLOWING KINDLING INDUCED SEIZURES

The study was designed to determine which type of cell death occurs following kindling induced seizures, and to determine which neurons die. For this purpose seizures were kindled from the entorhinal cortex. Following a range of 5-85 stage 5 seizures, rats were sacrificed, and the tissue was prepared for analysis. The TUNEL and silver impregnation methods were used to identify apoptotic or necrotic cell death, respectively. These methods were subsequently combined with immunocytochemistry, to determine if diseased neurons expressed somatostatin or the NMDA receptor (NMDAR1). The tissue analysis demonstrated that following kindling induced seizures, 1) hippocampal and extrahippocampal neurons die, 2) some neurons die through apoptosis, others through necrosis, and 3) some of the diseased neurons express somatostatin, others the NMDAR1 and that both subpopulations of neurons are present at hippocampal and extrahippocampal sites.

Enkephalin, substance P, and serotonin axonal input to c-fos-like immunoreactive neurons of the rat spinal cord.

Mustard oil, which stimulates small diameter afferents, was used to evoke the expression of the oncogene c-fos in the lumbar spinal cord. C-fos-like immunoreactivity was concentrated in, but not limited to, neuronal nuclei of laminae I and II of the lumbar dorsal horn. Double-label immunocytochemistry was used to determine if neurons which expressed c-fos-like immunoreactivity received axonal input from enkephalin-, substance P- or serotonin-immunoreactive neurons. The analysis of vibratome and semithin plastic-embedded tissue sections demonstrated that the majority of c-fos-like immunoreactive neurons received input from enkephalin-, substance P- or serotonin-immunoreactive axonal varicosities.

Oxytocin and vasopressin mRNA expression in rat hypothalamus following kainic acid-induced seizures.

In this study, the regulation of hypothalamic oxytocin and vasopressin messenger RNA expression following the induction of seizures was investigated by in situ hybridization. Following kainic acid-induced seizures, a significant increase in oxytocin messenger RNA in the paraventricular nucleus was demonstrated at 1.5 h, one and two weeks; its level decreased at three weeks and was significantly increased again at four weeks; at eight weeks the messenger RNA level still remained higher than that of controls. Vasopressin messenger RNA in the paraventricular nucleus was increased significantly only at 1.5 h following induction of seizures. The oxytocin messenger RNA level in the supraoptic nucleus was also increased early at 1.5 h and later at four weeks following seizures; however, these increases did not last as long as those in the paraventricular nucleus. Vasopressin messenger RNA in the supraoptic nucleus was also increased after the initial seizures; however, its messenger RNA level vacillated up and down throughout the post-seizure times studied. The earliest significant increase of vasopressin messenger RNA was at one week after seizures, and there was a late significant increase of vasopressin messenger RNA at three weeks after seizures. The present study demonstrates that following kainic acid-induced seizures both, the oxytocin and vasopressin messenger RNA expressions, were up-regulated and these up-regulations were long-term events. The increase of oxytocin messenger RNA in the paraventricular nucleus was more persistent than the others. The pattern of messenger RNA up-regulation was different for oxytocin and vasopressin, and different in the paraventricular nucleus and supraoptic nucleus. These different patterns of messenger RNA elevations suggest that the different components of the rat hypothalamus were regulated differentially by kainic acid-induced seizures.

The substantia nigra pars reticulata, seizures and Fos expression

The induction of the proto-oncogene c-fos has been used extensively to identify spatially distributed neural systems activated by seizures. The substantia nigra pars reticulata (SNpr) has been implicated as a critical structure in neural networks involved in the modulation of seizure expression, yet the SNpr has not been reported to express Fos following seizures induced in a variety of seizure paradigms. In this study we determined whether (1) the temporal characteristics of Fos induction in the SNpr were different than those of other brain areas following kindled seizures, (2) neurons in the SNpr possess the cellular machinery to express Fos, (3) Fos can be induced in SNpr by direct electrical stimulation, and (4) Fos expression is induced in the SNpr following kainate or pilocarpine-induced status epilepticus. Results indicate that Fos is not induced in SNpr at any time point (1-12 h) after kindled seizures, and that serum response factor, a constitutively expressed nuclear protein necessary for Fos expression, is present in SNpr neurons. Results further indicate that Fos expression in the SNpr is induced following either direct electrical stimulation or pilocarpine status, but not status elicited by kainate. We conclude that, in so far as the SNpr represents a critical structure for modulating seizure expression, seizure activity does not represent a sufficient stimulus to induce Fos in SNpr neurons. Further, the neural networks defined by Fos expression following seizure may be incomplete, and should be interpreted conservatively.

Activation of oxytocin-containing neurons of the paraventricular nucleus (PVN) following generalized seizures.

Due to the complex nature of generalized limbic seizures, marked disturbances in physiological homeostasis occur. Accompanying the motor manifestations which characteristically are associated with generalized limbic seizures, alterations in neuroendocrine, behavioral, and autonomic functions may be observed. The paraventricular nucleus (PVN) of the hypothalamus is known to play a significant role in such neuronal responses to stressful stimuli; however, the effect of seizures on hypothalamic neurons is unknown. We have used the immunocytochemical detection of the Fos protein to anatomically identify neurons in the PVN which are activated following generalized limbic seizures. To induce seizures, rats received intraperitoneal injections of kainic acid or were kindled from the entorhinal cortex. We have demonstrated that elicitation of generalized limbic seizures induces a dramatic number of neurons in the PVN to express the Fos protein. Numerous Fos‐immunolabeled neurons were identified in both the parvicellular and magnocellular component of the PVN. In the latter, this study clearly reveals a preferential and selective activation of oxytocin‐containing neurons, and it extends and supports the hypothesis that oxytocin plays a role in the bodys response to specific stress paradigms. Data suggest that an activation of the oxytocin neuronal system may be part of the adaptive mechanism that enables the hypothalamus to modulate and maintain an adequate response to stressors (e.g., generalized seizures) to regain homeostasis.

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.

Electrical stimulation of the rat ventral midbrain elicits antinociception via the dorsolateral funiculus

The pain-suppressive effects of focal electrical stimulation of sites throughout the ventral midbrain were examined in awake rats. Chronic bipolar electrodes were implanted in medial and lateral regions of the midbrain. Current thresholds for suppression of the tail-flick reflex in response to noxious heat were determined for both a biphasic and a monophasic stimulation parameter at each site. Stimulation of areas throughout the ventral midbrain produced tail-flick suppression (TFS), but no one area was consistently effective in all animals. Monophasic and biphasic stimulation were qualitatively equal in the duration of TFS and the distribution of effective sites. The production of TFS was not correlated with other behavioral reactions to brain stimulation. TFS appeared to be mediated by non-opiate pathways since naloxone administration (10 mg/kg) had no discernible effect on the production of TFS. The current threshold for producing TFS was extremely variable over both short (one half hour) and long (one week) intervals. The incidence of TFS from previously effective sites was significantly less following bilateral dorsolateral funiculus (DLF) lesions, indicating that the antinociceptive effects of ventral midbrain stimulation are mediated by this spinal pathway.

Coexistence of CRF peptide and oxytocin mRNA in the paraventricular nucleus

Several studies have reported coexistences of peptides in parvocellular neurons of the paraventricular nucleus (PVN). However, the coexistence of peptides in the magnocellular PVN is less clear. Controversy exists in particular about the coexistence of corticotropin-releasing factor (CRF) and oxytocin (OX). Although these peptides are present in distinct areas of the PVN, some overlap may exist. This study investigated a potential coexistence of OX and CRF in magno- and parvocellular PVN. The data demonstrate with clarity that neurons containing both the mRNA for OX and the peptide CRF are present in subpopulations of magnocellular and parvocellular neurons of the PVN.

Seizure-induced activation of enkephalin- and somatostatin-synthesizing neurons

The extent of the neuronal network that is activated by kainic acid-induced seizures was anatomically identified and neurochemically characterized. Seizure-activated neurons were identified through the immunocytochemical demonstration of Fos protein in neuronal nuclei. These seizure-activated neurons were characterized by determining if they contained the mRNA for somatostatin or enkephalin, using in situ hybridization procedures. The results demonstrate that a majority of enkephalin- and somatostatin-synthesizing neurons expressed the Fos protein following seizures and that they represent a major component of the kainic acid-induced, seizure-activated neuronal network.

The kindling-activated neuronal network: Recruitment of somatostatin-synthesizing neurons

The present study demonstrates the anatomical extent of the kindling-activated neuronal network in general, and specifically the recruitment of extrahippocampal somatostatin (SST)-synthesizing neurons into this network. It has been known that SST neurons of the hippocampal formation are activated during episodes of seizure, however, it was not known if this activation was a local event or extended to other areas in the brain. We were therefore interested in determining if and which SST neurons outside the hippocampal formation might be recruited into this seizure-activated neuronal network. Using the kindling model of seizure elicitation, expression of the Fos protein in activated, depolarized neurons was utilized to identify seizure-activated neurons. Subsequently, the mRNA for SST was identified through in situ hybridization in the same tissue section, allowing the identification of seizure-activated, SST-synthesizing neurons. The results show that: (a) the majority of SST-synthesizing neurons in the forebrain and diencephalon became activated during the kindling development; (b) their recruitment into the kindling-activated neuronal network occurred progressively; and, (c) these SST-synthesizing neurons represented a component of the kindling-activated neuronal network throughout the development of kindling-induced seizures.