Blockade of calcium entry accelerates arsenite-mediated apoptosis in rat cerebellar granule cells

Arsenical exposure can cause defects in the central nervous system, yet the underlying cellular and molecular mechanisms are largely unknown. We have recently demonstrated that sodium arsenite induces apoptosis of cultured cortical and cerebellar neurons, suggesting that arsenite-induced neuronal apoptosis may contribute to at least some of its neurotoxic effects. Here we investigated the effect of Ca2+ on arsenite-mediated cerebellar granule neuron death. Sodium arsenite induced apoptosis in cerebellar neurons which were maintained in the presence of serum and depolarizing concentrations of potassium chloride (25 mM KCI). Under these conditions, inhibition of calcium entry by N-methyl-D-aspartate (NMDA) receptor blocker DL-aminophosphonovalerate (APV) or calcium channel antagonist nifedipine increased arsenite-induced apoptosis, while APV or nifedipine alone had little effect on cell viability. In cortical neurons or cerebellar neurons maintained at low potassium (5 mM), arsenite also induced apoptosis. However, the addition of APV or nifedipine did not alter levels of arsenite-induced apoptosis. These data suggest that arsenite-mediated apoptosis is regulated by intracellular calcium levels.     

The secretory response of hypothalamic β-endorphin neurons to acute and chronic nicotine treatments and following nicotine withdrawal

In the present study, we determined the effect of acute and chronic nicotine treatments on the secretion of immunoreactive β-endorphin (IR-β-EP) and cell viability of cultured hypothalamic neurons. Also, we determined the secretory response of IR-β-EP following withdrawal from a long-term nicotine treatment. Fetal hypothalamic cells were dissociated and maintained in cultures for 9 days and were treated with various doses of nicotine (1, 6,12 and 18 μM) for 6 h (acute treatment) or treated with nicotine at 12 h intervals for 96 h (chronic treatment). Determination of IR-β-EP concentrations in the media revealed that 6–18 μM doses of nicotine increased IR-β-EP secretion from these cultures for a period of 24 h; after this period, the cultured cells did not respond to these doses of nicotine. The desensitization of β-EP neurons 24 h after treatment with nicotine did not appear to be related to the loss of viable cells. Determination of withdrawal response after 72 h of constant nicotine (6 μM) treatments revealed that the hypothalamic neurons secrete elevated amounts of IR-β-EP for a period of 72 h after nicotine withdrawal. These results suggest that: 1) acute treatment with nicotine stimulates hypothalamic IR-β-EP release; 2) chronic nicotine treatment desensitizes β-EP-secreting neurons and, 3) β-EP neurons in primary culture show withdrawal response to nicotine.     

Evidence that potassium channels regulate prolactin secretion in GH4C1 cells by causing extracellular calcium influx

Tetraethylammonium (TEA), a K+ channel blocker, induced prolactin (PRL) secretion in GH4C1 cells in a dose-dependent manner when applied at a concentration from 1-20 mM. During continuous exposure to TEA, a significant increase in PRL secretion occurred by 20 min and the response was sustained until the end of a 60-min exposure. Blocking Ca2+ influx by employing a Ca(2+)-depleted medium or the Ca2+ channel blocker, nifedipine, prevented induction of PRL secretion by 20 mM TEA. Preincubation of the cells for 10 min with 20 mM TEA did not inhibit PRL secretion induced by thyrotropin-releasing hormone (TRH), phorbol 12-myristate 13-acetate (TPA) or by cell swelling produced by 30% medium hyposmolarity, but significantly depressed that induced by depolarizing 30 mM K+. BaCl2, another K+ channel blocker, had the same effect on PRL secretion as TEA. The data suggest that blocking K+ channels may cause membrane depolarization, thereby inducing Ca2+ influx which is a potent stimulus for PRL secretion in GH4C1 cells.     

Divergent Effects of Acute Depolarization on Somatostatin Release and Protein Synthesis in Cultured Fetal and Neonatal Rat Brain Cells

The influence of membrane depolarization on somatostatin secretion and protein synthesis by fetal and neonatal cerebrocortical neurons was studied. Cortical cells obtained by mechanical dispersion were maintained as monolayer cultures for 8 days. The ability of fetal cerebrocortical and hypothalamic cells to release immunoreactive somatostatin (IR-SRIF) was confirmed. Total protein synthesis was determined by the incorporation of [3H]phenylalanine into trichloroacetic acid-precipitable proteins. To study the effect of acute depolarization on protein synthesis, cells were incubated for 30 min with [3H]phenylalanine or [3H]leucine and the depolarizing agent. In fetal cerebrocortical cells, potassium (30 and 56 mM) decreased protein synthesis and RNA levels and increased IR-SRIF release. Depolarization by veratridine, a sodium channel activator, induced a similar effect. The effect of veratridine on IR-SRIF and protein synthesis was reversed by tetrodotoxin, a sodium channel blocker, or verapamil, a calcium channel blocker. These findings suggest that protein synthesis by cerebrocortical cells is decreased in fetal brain cells by membrane depolarization and is dependent on Na+ and Ca2+ entry into cells. In postnatal (day 7) cerebrocortical cells, depolarization induced by high potassium concentrations led to a concomitant increase in protein synthesis, RNA content, and somatostatin release. These findings indicate that depolarization of the cellular membrane is coupled to an increase in protein synthesis in neonatal, but not in fetal, dispersed brain cells.     

Endorphinergic and alpha-noradrenergic systems in the paraventricular nucleus: effects on eating behavior

Brain cannulated rats were injected with the opioid peptide beta-endorphin (beta-EP) directly into the hypothalamic paraventricular nucleus (PVN) where norepinephrine (NE) is most effective in stimulating eating behavior. Beta-Endorphin (1.0 nmole) reliably increased food intake in satiated animals, and this response was blocked by local administration of the selective opiate antagonist naloxone. The eating induced by beta-EP was positively correlated in magnitude with the NE response and, like NE, was antagonized by PVN injection of the alpha-noradrenergic blocker phentolamine. Naloxone had no effect on NE-induced eating, and the dopaminergic blocker fluphenazine failed to alter either beta-EP or NE eating. When injected simultaneously, at maximally effective doses, beta-EP and NE produced an eating response which was significantly larger than either of the responses elicited separately by beta-EP or NE and was essentially equal to the sum of these two responses. The evidence obtained in this study suggests that beta-EP and NE stimulate food ingestion through their action on PVN opiate and alpha-noradrenergic receptors, respectively, and that beta-EP's action is closely related to, and in part may be dependent upon, the PVN alpha-noradrenergic system for feeding control.     

Cytoplasmic changes in primary cultured adult mouse sensory neurons induced by ethanol and acetaldehyde treatments.

Primary cultured sensory neurons prepared from adult mice were maintained for 8 days in vitro. Such cultures were exposed to either a range of ethanol concentrations (50-300 mM) or acetaldehyde (0.5-2 mM) in serum-free medium for up to 24 h. Treated neuronal cultures, together with untreated controls in both the presence and absence of serum, were prepared for transmission electron microscopy. Nuclear morphology was not changed following treatment with either substance at the doses studied. A number of changes were observed, however, in the cytoplasm of neurons, and these were intensified by an increase in concentration and the length of exposure. Acetaldehyde induced effects at a much lower concentration than was required to induce a response with ethanol. Myelin lamellae loosely wound around dense granular core material appeared in multivesicular bodies at low doses. The prevalence of these increased with concentrations of 100 mM ethanol and 1 mM acetaldehyde; the numbers of lamellae in each myelin figure also increased but the core material was less prominent. Electron-dense bodies were also evident at higher dosages together with evidence of vacuolation of the endoplasmic reticulum and Golgi complexes. Mitochondrial profiles similar to those in untreated neurons persisted throughout the exposure periods. The generation of these inclusions may reflect a mechanism of membrane turnover, both of internal systems and cell membrane cycling, as a response to alcohol and aldehyde treatment.     

Functional Aspects of Calcium Channels of Splanchnic Neurons and Chromaffin Cells of the Rat Adrenal Medulla

Effects of the inorganic calcium channel blockers zinc, manganese, cadmium, and nickel on secretion of catecholamines from the perfused adrenal gland of the rat were investigated. Secretion of catecholamines evoked by splanchnic nerve stimulation (1 and 10 Hz) was not affected by nickel (100 microM), partially blocked (50%) by cadmium (100 microM), and almost completely blocked (90%) by zinc (1 mM) or manganese (2 mM). A combination of nickel and cadmium inhibited nerve stimulation-evoked secretion by 80-90%. Catecholamine secretion evoked by direct stimulation of chromaffin cells by acetylcholine (50 micrograms), nicotine (5 microM), muscarine (50 micrograms), and K+ (17.5 mM) was not blocked by either cadmium, nickel, or their combination. However, zinc and manganese almost abolished nicotine- and K(+)-evoked secretion of catecholamines. None of the above agents had any effect on the secretion evoked by muscarine. Acetylcholine-evoked secretion of catecholamines was only partially reduced (50%) by zinc and manganese. We draw the following conclusions from the above findings: (a) cadmium plus nickel selectively blocks the calcium channels of splanchnic neurons but has no effect on calcium channels of the chromaffin cells; (b) zinc and manganese do not discriminate between calcium channels of neurons and calcium channels of chromaffin cells; (c) partial inhibition of acetylcholine-evoked secretion by inorganic calcium channel blockers is consistent with the idea that activation of nicotinic receptors increases Ca2+ influx, and activation of muscarinic receptors mobilizes intracellularly bound Ca2+, which is not affected by calcium channel blockers.     

Modulation of Ca2+ channels by atrial natriuretic peptide in the bovine adrenal glomerulosa cell.

In the bovine adrenal glomerulosa cell, calcium influx through voltage-dependent calcium channels is critical to maintaining an aldosterone secretory response. In patch clamp, atrial natriuretic peptide (ANP) inhibits T-type calcium channel current yet stimulates L-type calcium channel current. In the present study the channel effects of ANP observed in the patch-clamp configuration were extended and related to populations of cells. We observed the following. (i) The effect of ANP on T-channel current resulted in the reduction in the open state probability. ANP decreased the mean open state duration from 14.2 to 1.8 ms/sweep. (ii) In the weakly depolarized cell stimulated by 8 mM K+, ANP reduced the level of aequorin luminescence (a measure of cytosolic calcium) and completely inhibited the stimulated rate of aldosterone secretion, returning it to prestimulation values. These effects are consistent with a decrease in net calcium channel influx and the reported inhibition of T-channel current. In contrast, the calcium channel blocker, nitrendipine, which at low dose selectively blocks L-type calcium channel flux, only slightly reduced luminescence, and partially inhibited the sustained secretory response. (iii) In the strongly depolarized cell, stimulated by 60 mM K+, ANP increased the level of aequorin luminescence consistent with an increase in net calcium channel influx and the reported stimulation of L-channel current. These results indicate that under physiological conditions the inhibition of T-type calcium channels may be involved in the inhibition of the aldosterone secretion induced by ANP.     

The response of primary cultured adult mouse sensory neurons to ethanol, propanol, acetaldehyde and acrolein treatments

Primary cultures of adult mouse sensory neurons maintained for 8 days in vitro (8 div), in both the presence of non-neuronal cell (NNC) outgrowth and in NNC-reduced cultures, were exposed to doses of ethanol, propanol, acetaldehyde and acrolein. The effects on cell viability were monitored: LD50's of 600 microM acrolein and 100 mM propanol were obtained after 24 h exposures and after 48 h with 1 mM acetaldehyde and 500 mM ethanol. Morphological effects were evident by scanning electron microscopy with sub-acute doses for each agent, using both lower concentrations and shorter exposures. Membrane pitting of the perikaryon and a reduction in the proportion of neurons bearing neurites were common signs of toxic insult. The neurites of treated cells were thicker and more irregular than those of untreated cells; this proved a good indicator of specific neurotoxicity rather than merely a cytotoxic response. Fetal calf serum in the medium lessened the response of neurons to ethanol treatments. Comparison with other in vitro studies suggests these primary cultures are a more sensitive system than established cell lines of neuronal origin for use in neurotoxicity testing.     

The response of primary cultured adult mouse sensory neurons to ethanol,propanol, acetaldehyde and acrolein treatments

Primary cultures of adult mouse sensory neurons maintained for 8 days in vitro (8 div), in both the presence of non-neuronal cell (NNC) outgrowth and in NNC-reduced cultures, were exposed to doses of ethanol, propanol, acetaldehyde and acrolein. The effects on cell viability were monitored: LD50’s of 600 μM acrolein and 100 mM propanol were obtained after 24 h exposures and after 48 h with 1 mM acetaldehyde and 500 mM ethanol. Morphological effects were evident by scanning electron microscopy with sub-acute doses for each agent, using both lower concentrations and shorter exposures. Membrane pitting of the perikaryon and a reduction in the proportion of neurons bearing neurites were common signs of toxic insult. The neurites of treated cells were thicker and more irregular than those of untreated cells; this proved a good indicator of specific neurotoxicity rather than merely a cytotoxic response. Fetal calf serum in the medium lessened the response of neurons to ethanol treatments. Comparison with other in vitro studies suggests these primary cultures are a more sensitive system than established cell lines of neuronal origin for use in neurotoxicity testing.     

Comparative Effects of Chronic Exposure to Ethanol and Calcium Channel Antagonists on Calcium Channel Antagonist Receptors in Cultured Neural (PC12) Cells

Treatment with 200 mM ethanol for 6 days increased binding of the Ca2+ channel antagonist, (+)-[3H]PN 200-110, to intact PC12 cells in culture. Enhancement of binding by ethanol was due to an increase in binding site number without appreciable change in binding affinity. Long-term exposure to Ca2+ channel antagonist drugs (nifedipine, verapamil, or diltiazem), which, like ethanol, acutely inhibit Ca2+ flux, failed to alter (+)-[3H]PN 200-110 binding to PC12 membranes. Cotreatment of ethanol-containing cultures with the Ca2+ channel agonist, Bay K 8644, did not attenuate the response to ethanol; instead, chronic exposure to Bay K 8644 alone increased (+)-[3H]PN 200-110 binding. These results suggest that chronic exposure to ethanol increases Ca2+ channel antagonist receptor density in living neural cells, but that acute inhibition of Ca2+ flux by ethanol is unlikely to trigger this response.     

Modulation of sprouting in organ culture after axotomy of an identified molluscan neuron.

We examined a variety of factors that might modulate the initiation of neurite outgrowth in an attempt to identify means by which its initiation might be accelerated. We examined this initiation from an identified molluscan neuron, Helisoma trivolvis buccal neuron B5 after axotomy, and determined whether the site of injury, temperature, ion channel blockers, pH, the second messenger cAMP, and protein synthesis affect the initiation of neurite outgrowth. Neurite outgrowth was assayed from axotomized neurons by filling the neurons intracellularly with Lucifer Yellow and examining the percentage of axons that extended (sprouted) new process after 9 or 24 h in organ culture. About one-third (31%) of axotomized neurons sprouted from the site of injury after 9 h (n = 22), and 88% (n = 20) sprouted after 24 h in saline at 22 degrees-24 degrees C when the injury was located 800 microns from the soma. Elevating the temperature to 32 degrees C or moving the lesion site to 400 or 1500 microns from the soma did not significantly alter the incidence of sprouting. Blocking sodium channels with tetrodotoxin [TTX (2 x 10(-5) M)] did not significantly reduce the incidence of sprouting, whereas the sodium channel agonist, veratridine (10(-5) M) did. The calcium channel blocker lanthanum (10(-6)-10(-4) M), stimulated neurite outgrowth; however, the organic calcium channel blocker verapamil (10(-3)-10(-5) M), and the calcium ionophore A23187 (10(-5) M), had no effect on sprouting. Exposure of neurons to the potassium channel blocker tetraethylammonium [TEA (20 mM)], elevation of intracellular pH with NH4Cl (5 mM), or treatment with the adenylate cyclase activator forskolin (10(-5) M) reduced the incidence of sprouting, whereas dideoxy-forskolin (10(-5) M) had no effect. Inhibition of protein synthesis with anisomycin (2 x 10(-4) to 2 x 10(-6) M) did not significantly suppress sprouting 24 h after axotomy. Both D and L isomers of glutamate (300 microM) stimulated sprouting. The present results suggest that the initiation of sprouting is regulated locally at or near the site of injury, and that blocking specific ion channels may either inhibit or enhance the initiation of neurite outgrowth.     

KCNQ Channels Show Conserved Ethanol Block and Function in Ethanol Behaviour

In humans, KCNQ2/3 channels form an M-current that regulates neuronal excitability, with mutations in these channels causing benign neonatal familial convulsions. The M-current is important in mechanisms of neural plasticity underlying associative memory and in the response to ethanol, with KCNQ controlling the release of dopamine after ethanol exposure. We show that dKCNQ is broadly expressed in the nervous system, with targeted reduction in neuronal KCNQ increasing neural excitability and KCNQ overexpression decreasing excitability and calcium signalling, consistent with KCNQ regulating the resting membrane potential and neural release as in mammalian neurons. We show that the single KCNQ channel in Drosophila (dKCNQ) has similar electrophysiological properties to neuronal KCNQ2/3, including conserved acute sensitivity to ethanol block, with the fly channel (IC₅₀ = 19.8 mM) being more sensitive than its mammalian ortholog (IC₅₀ = 42.1 mM). This suggests that the role of KCNQ in alcohol behaviour can be determined for the first time by using Drosophila. We present evidence that loss of KCNQ function in Drosophila increased sensitivity and tolerance to the sedative effects of ethanol. Acute activation of dopaminergic neurons by heat-activated TRP channel or KCNQ-RNAi expression produced ethanol hypersensitivity, suggesting that both act via a common mechanism involving membrane depolarisation and increased dopamine signalling leading to ethanol sedation.     

Chronic Ethanol Exposure Potentiates NMDA Excitotoxicity in Cerebral Cortical Neurons

Abstract: The effect of acute and chronic ethanol exposure on excitotoxicity in cultured rat cerebral cortical neurons was examined. Neuronal death was quantitated by measuring the accumulation of lactate dehydrogenase (LDH) in the culture media 20 h after exposure to NMDA. Addition of NMDA (25–100 μ M ) to the culture dishes for 25 min in Mg²⁺-free buffer resulted in a dose-dependent increase in LDH accumulation. Phase-contrast microscopy revealed obvious signs of cellular injury as evidenced by granulation and disintegration of cell bodies and neuritic processes. Chronic exposure of neuronal cultures to ethanol (100 m M ) for 96 h followed by its removal before NMDA exposure, significantly increased NMDA-stimulated LDH release by 36 and 22% in response to 25 μ M and 50 μ M NMDA, respectively. Neither basal LDH release nor that in response to maximal NMDA (100 μ M ) stimulation was altered by chronic alcohol exposure. In contrast to the effects of chronic ethanol on NMDA neurotoxicity, inclusion of ethanol (100 m M ) only during the NMDA exposure period significantly reduced LDH release by ∼ 50% in both control and chronically treated dishes. This reduction by acute ethanol was also observed under phase-contrast microscopy as a lack of development of granulation and a sparing of disintegration of neuritic processes. These results indicate that chronic exposure of ethanol to cerebral cortical neurons in culture can sensitize neurons to excitotoxic NMDA receptor activation.     

Estrogen enhances expression of the complement C5a receptor and the C5a-agonist evoked calcium influx in hormone secreting neurons of the hypothalamus

In the present study we examined presence of the complement C5a receptor (C5aR) in hypothalamic neurosecretory neurons of the rodent brain and effect of estrogen on C5aR expression. Whole cell patch clamp measurements revealed that magnocellular neurons in the supraoptic and paraventricular nuclei of hypothalamic slices of the rats responded to the C5aR-agonist PL37-MAP peptide with calcium ion current pulses. Gonadotropin-releasing hormone (GnRH) producing neurons in slices of the preoptic area of the mice also reacted to the peptide treatment with inward calcium current. PL37-MAP was able to evoke the inward ion current of GnRH neurons in slices from ovariectomized animals. The amplitude of the inward pulses became higher in slices obtained from 17beta-estradiol (E2) substituted mice. Calcium imaging experiments demonstrated that PL37-MAP increased the intracellular calcium content in the culture of the GnRH-producing GT1-7 cell line in a concentration-dependent manner. Calcium imaging also showed that E2 pretreatment elevated the PL37-MAP evoked increase of the intracellular calcium content in the GT1-7 cells. The estrogen receptor blocker Faslodex in the medium prevented the E2-evoked increase of the PL37-MAP-triggered elevation of the intracellular calcium content in the GT1-7 cells demonstrating that the effect of E2 might be related to the presence of estrogen receptor. Real-time PCR experiments revealed that E2 increased the expression of C5aR mRNA in GT1-7 neurons, suggesting that an increased C5aR synthesis could be involved in the estrogenic modulation of calcium response. These data indicate that hypothalamic neuroendocrine neurons can integrate immune and neuroendocrine functions. Our results may serve a better understanding of the inflammatory and neurodegeneratory diseases of the hypothalamus and the related neuroendocrine and autonomic compensatory responses.     

Calcium effects on progesterone accumulation and oocyte maturation in cultured follicles of Rana pipiens

Pituitary homogenates (FPH) provoke a cascade of responses in the amphibian ovarian follicle, culminating in progesterone biosynthesis and oocyte maturation (GVBD). Calcium may play an important role as an intracellular second messenger in regulating these physiological responses. Experiments were carried out on cultured, isolated follicles of Rana pipiens to assess the effects of varying extracellular calcium on follicular progesterone accumulation and oocyte maturation. In hormonally unstimulated follicles, an increase in extracellular Ca2+ alone produced a significant increase in progesterone in methanol extracts of follicles after 4 hours of culture, and in some cases also provoked oocyte maturation assessed after 24 hours of culture. In no case did elevated Ca2+ alone stimulate maximal progesterone accumulation as compared with FPH-stimulated follicles, although the time-course of accumulation was similar. The calcium ionophore, A-23187, similarly increased progesterone accumulation in a dose-dependent manner when introduced in amphibian Ringer's (1.35 mM Ca2+), but inhibited progesterone elevation caused by increasing calcium concentrations in the culture media and FPH stimulation. Depleting free calcium from the culture medium with graded doses of the chelator EGTA decreased FPH-induced progesterone accumulation and inhibited FPH- and progesterone-induced GVBD. The calcium channel blocker, verapamil, also inhibited FPH-induced progesterone accumulation and GVDB in a dose-dependent manner, while having no effect on progesterone-induced meiotic resumption. These data strongly implicate intracellular calcium levels regulating progesterone production by ovarian follicle cells and subsequent oocyte maturation.     

Interleukin-6 stimulates gonadotropin-releasing hormone secretion from rat hypothalamic cells

There are reports that both interleukin-1 beta and interleukin-6 (IL-6) stimulate the release of adrenocorticotropin through stimulation of hypothalamic corticotropin-releasing factor. We established a primary culture system for hypothalamic neurons producing gonadotropin-releasing hormone (GnRH) and examined whether IL-6 stimulated their GnRH secretion. We demonstrated immunohistochemically that some of these neurons contained GnRH-like immunoreactivity. In primary cultures of these GnRH neurons, we found that the calcium ionophore A23187 stimulated GnRH secretion in a dose- and time-dependent manner. These hypothalamic cells secreted IL-6 spontaneously, producing about 10 ng/l in 24 h, and their IL-6 secretion was significantly stimulated by E2 at 10(-9)-10(-8) mol/l. This stimulatory effect was observed within 3 h. IL-6 also stimulated the release of GnRH in a dose- and time-dependent manner, and these effects of IL-6 were significantly blocked by anti-IL-6 antiserum. These results suggest that the central action of IL-6 on the GnRH neurons may be an important physiological event in the hypothalamus.     

A comparison between acute exposures to ethanol and acetaldehyde on neurotoxicity, nitric oxide production and NMDA-induced excitotoxicity in primary cultures of cortical neurons

Chronic exposure of primary neuronal cultures to ethanol has been shown to potentiate N-methyl-D-aspartate (NMDA) receptor-mediated processes, such as nitric oxide (NO) formation and excitotoxicity. In the present study, we compared the effects of acute ethanol and acetaldehyde on NMDA receptor-mediated excitotoxicity and NO production in primary cultures of rat cortical neurons. The delayed cell death induced by NMDA (300 mM, 25 min) was evaluated by morphological examination and by measuring the release of the cytotoxic indicator, lactate dehydrogenase, in the culture media 24 hours after the NMDA exposure. The accumulation of nitrite, as an index of NO production, was also measured 24 hours after NMDA treatment. NMDA caused a dose-dependent cell death and nitrite accumulation, both effects were blocked by pretreatment of MK-801 (100 microM). Acute exposure to ethanol (1-1000 mM) or acetaldehyde (0.1-1 mM) for 35 minutes did not affect neuronal viability in the following 24-hr period. However, acute exposure to acetaldehyde (> or =10 mM) was neurotoxic. Neither ethanol nor acetaldehyde changed basal nitrite levels in the culture media. Acute ethanol (50-400 mM, 10 min) given before the NMDA treatment (25 min) resulted in a concentration-dependent suppression of the delayed cell death. The NMDA-induced NO production was, however, not affected by ethanol. Neither the NMDA excitotoxicity nor NO production was affected by acute ethanol given after NMDA treatment. Acute acetaldehyde (0.01-0.5 mM, 10 min) given before or after NMDA treatment had no effect on delayed NMDA neurotoxicity and NO production. Our data suggest that acute exposure to ethanol is not neurotoxic and is even protective against delayed NMDA-excitotoxicity when given before but not after NMDA treatment. Neither NO nor metabolism of ethanol to acetaldehyde is required for ethanol-mediated suppression of NMDA excititoxicity. Acetaldehyde, on the other hand, is toxic by itself at low concentrations (> or =10 mM). Furthermore, acute exposure to non-toxic concentrations of acetaldehyde could not protect cortical neurons against NMDA-induced excitotoxicity.     

Interleukin-1beta depolarizes magnocellular neurons in the paraventricular nucleus of the hypothalamus through prostaglandin-mediated activation of a non selective cationic conductance

Interleukin-1beta (IL-1beta) is involved in hypothalamic regulation of the neuroimmune response by influencing the synthesis and secretion of corticotropin releasing hormone (CRH), vasopressin (VP) and other stress-related mediators. VP secretion from magnocellular (MNC) neurons of the paraventricular nucleus (PVN) of the hypothalamus at the posterior pituitary and/or median eminence contributes to increasing adrenocorticotropin hormone (ACTH) output and ultimately glucocorticoid release, which then contributes to the stress response. In this study, using whole-cell patch clamp recordings from neurons in a slice preparation of the rat PVN, we show that MNC neurons are also influenced by IL-1beta. In response to 1 nM IL-1beta, 62% of MNC neurons tested depolarized (mean depolarization=10.9+/-1.4 mV); effects which were maintained in the presence of a sodium channel blocker, tetrodotoxin (TTX). The effects of IL-1beta on MNC neurons were blocked in the presence of a specific cyclooxygenase (COX)-2 inhibitor, NS-398, indicating a dependence on prostaglandins (PG) in mediating these effects. In response to direct application of 1 muM PGE2, 57% of MNC neurons depolarized, exhibiting a membrane potential change similar to that induced by IL-1beta (mean depolarization=7.8+/-1.1 mV). Voltage clamp experiments examining the effects of PGE2 on the currents evoked by slow voltage ramps revealed activation of a conductance characteristic of a non-selective cationic conductance (NSCC) (voltage-independent, with a reversal potential of -41.8+/-7.6 mV), suggesting that this prostanoid directly modifies cationic currents in MNC neurons. These data provide evidence that IL-1beta depolarizes MNC neurons in the PVN as a result of prostaglandin-mediated activation of a NSCC.     

Role of a novel maintained low-voltage-activated inward current permeable to sodium and calcium in pacemaking of insect neurosecretory neurons

Among ionic currents underlying neuronal pacemaker activity, low-threshold-activated calcium currents contribute to setting the threshold for spike firing. In the insect central nervous system, dorsal unpaired median (DUM) neurons are capable of generating spontaneous electrical activity. It has previously been shown that two distinct (transient and maintained) low-voltage-activated (LVA) calcium currents are responsible for the generation of the pacemaker potential. Whole-cell recordings in voltage- and current-clamp mode were obtained from short-term cultured DUM neurons. Using 100 mM sodium and 2 mM calcium as charge carrier in the external solution as well as conditions that eliminate calcium currents (0.5 mM CdCl₂), voltage-clamp experiments showed that a hitherto unanticipated LVA maintained inward current, activated at around −60 mV, was present. The current amplitude was strongly dependent on internal ATP concentration. Sodium-free solution reduced by 80% the current amplitude. Increasing (5 mM) or decreasing (calcium-free) external calcium concentrations enhanced or reduced, respectively, the maximum conductance without any effect on the voltage dependence. This novel ion channel was permeable to barium but manipulating internal or external magnesium concentrations was without effect on current amplitude or reversal potential. Based on IC₅₀ values, the maintained current was 50-fold less sensitive to TTX than the classical transient voltage-dependent sodium current. Furthermore, it was insensitive to ethosuximide and halothane. Voltage-dependent inactivation analysis revealed an unexpected calcium-sensitive process that involved calcineurin. From these results it appears that, besides the two LVA calcium currents previously described, another LVA maintained inward current permeable to both sodium and calcium was also involved in the generation of the predepolarization. Based on these findings, we propose that a novel calcium-dependent mechanism is involved in the regulation of the pacemaker activity.