Effects of omega-conotoxin MVIIC on veratridine-induced cytotoxicity and cytosolic Ca(2+) oscillations

Cytotoxicity Models in Chromaffin Cells to Evaluate Neuroprotective Compounds

Primary cultures of bovine chromaffin cells are considered a good model to evaluate potential neuroprotective compounds for two major reasons: (i) they share many common features to neurons as they synthesize, store, and release neurotransmitters; they are excitable cells that express voltage-dependent calcium, potassium, and sodium channels; they express different neuronal receptor subtypes; and (ii) they can be easily cultured in high quantities from adult animals; as adult para-neurons, they can be used to reproduce different neurodegenerative-like cytotoxicity models. In this chapter, we describe protocols to mimic calcium overload (veratridine and thapsigargin) and oxidative stress (rotenone plus oligomycin-A and 6-hydroxydopamine) to evaluate potential neuroprotective compounds.

ITH33/IQM9.21 provides neuroprotection in a novel ALS model based on TDP-43 and Na+/Ca2+ overload induced by VTD

Therapeutic options for amyotrophic lateral sclerosis (ALS) are scarce and controversial. Although the aetiology of neuronal vulnerability is unknown, growing evidence supports a complex network in which multiple toxicity pathways, rather than a single mechanism, are involved in the pathogenesis of ALS. However, most cellular models only explain single pathogenic mechanisms. The present study proposes the two main cytotoxic mechanisms: (1) veratridine (VTD), which induced Na⁺ and Ca²⁺ overload; and (2) the TARD DNA-binding protein 43 (TDP-43) in NSC-34 cell line as an in vitro model of ALS. The study was carried out by MTT as an indirect measurement of cell viability and by flow cytometry to determine cell death stages. The impact of Ca²⁺ overload combined with TDP-43 overexpression increased early apoptosis of NSC-34 cells. Furthermore, we found that ITH33/IQM9.21 (ITH33) exerted a neuroprotective effect in this model by reducing activation of the apoptotic pathway. Therefore, treatment with VTD in TDP-43 overexpressing NSC-34 cells is a good in vitro ALS model that makes it possible to test new neuroprotective compounds such as ITH33.

Phoneutria spider toxins block ischemia-induced glutamate release and neuronal death of cell layers of the retina

PURPOSE

To investigate the effect of calcium channel blockers, spider toxins, on cell viability and the glutamate content of ischemic retinal slices.

METHODS

Rat retinal slices were subjected to ischemia via exposure to oxygen-deprived low-glucose medium for 45 minutes. Slices were either treated or not treated with the toxins PhTx3, Tx3-3, and Tx3-4. After oxygen-deprived low-glucose insult, glutamate content and cell viability were assessed in the slices by confocal and optical microscopy.

RESULTS

In the retinal ischemic slices that were treated with PhTx3, Tx3-3, and Tx3-4, confocal imaging showed a decrease in cell death of 79.5 ± 3.1%, 75.5 ± 5.8%, and 61 ± 3.8%, respectively. Neuroprotective effects were also observed 15, 30, 60, and 90 minutes after the onset of the retinal ischemic injury. As a result of the ischemia, glutamate increased from 6.2 ± 1.0 nMol/mg protein to 13.2 ± 1.0 nMol/mg protein and was inhibited by PhTx3, Tx3-3, and Tx3-4 to 8.6 ± 0.7, 8.8 ± 0.9, and 7.4 ± 0.8 nMol/mg protein, respectively. Histologic analysis of the live cells in the outer, inner, and ganglion cell layers of the ischemic slices showed a considerable reduction in cell death by the toxin treatment.

CONCLUSION

Spider toxins reduced glutamate content and cell death of retinal ischemic slices.

Protective effect of retinal ischemia by blockers of voltage-dependent calcium channels and intracellular calcium stores

In the present study, the neuroprotective effect of blockers of voltage-dependent calcium channels (VDCC) and intracellular calcium stores on retinal ischemic damage induced by oxygen deprivation-low glucose insult (ODLG) was investigated. Retinal damage induced by ODLG was dependent on the calcium concentration in the perfusion medium. When incubated in medium containing 2.4 mM CaCl(2), cell death in ischemic retinal slices treated with blockers of VDCC, omega-conotoxin GVIA (1.0 microM), omega-conotoxin MVIIC (100 nM) and nifedipine (1.0 microM), was reduced to 62 +/- 2.3, 46 +/- 4.3 and 47 +/- 3.9%, respectively. In the presence of blockers of intracellular calcium stores, dantrolene (100 microM) and 2-APB (100 microM), the cell death was reduced to 46 +/- 3.2 and 55 +/- 2.9%, respectively. Tetrodotoxin (1.0 microM), reducing the extent of the membrane depolarization reduces the magnitude of calcium influx trough VDCC causing a reduction of the cell death to 55 +/- 4.3. Lactate dehydrogenase content of untreated ischemic retinal slices was reduced by 37% and treatment of ischemic slices with BAPTA-AM (100 microM) or 2-APB (100 microM) abolished the leakage of LDH. Dantrolene (100 microM) and nifedipine (1.0 microM) partially blocked the induced reduction on the LDH content of retinal ischemic slices. Histological analysis of retinal ischemic slices showed 40% reduction of ganglion cells that was prevented by BAPTA-AM or dantrolene. 2-APB partially blocked this reduction whilst nifedipine had no effect, p > 0.95. Conclusion Blockers of VDCC and intracellular calcium-sensitive receptors exert neuroprotective effect on retinal ischemia.

Neuroprotective effect on brain injury by neurotoxins from the spider Phoneutria nigriventer

The role of calcium channels blockers in ischemic condition has been well documented. The PhTx3 neurotoxic fraction of the spider Phoneutria nigriventer venom is a broad-spectrum calcium channel blocker that inhibits glutamate release, calcium uptake and also glutamate uptake in synaptosomes. In the present study we describe the effect of PhTx3 (1.0 microg/mL), omega-conotoxin GVIA (1.0 micromol/L) and omega-conotoxin MVIIC (100 nmol/L) on neuroprotection of hippocampal slices and SN56 cells subjected to ischemia by oxygen deprivation and low glucose insult (ODLG). After the insult, cell viability in the slices and SN56 cells was assessed by confocal microscopy and epifluorescence, using live/dead kit containing calcein-AM and ethidium homodimer. Confocal images of CA1 region of the rat hippocampal slices subjected to ischemia insult and treated with omega-conotoxin GVIA, omega-conotoxin MVIIC and PhTx3 showed a percentage of dead cells of 68%, 54% and 18%, respectively. The SN56 cells subjected to ischemia were almost completely protected from damage by PhTx3 while with omega-conotoxin GVIA or omega-conotoxin MVIIC the cell protection was only partial. Thus, PhTx3 provided robust ischemic neuroprotection showing potential as a novel class of agents that targets multiple components and exerts neuroprotection in in vitro model of brain ischemia.

Investigation of the modulation of glutamate release by sodium channels using neurotoxins

The modulation of neurotransmitter release by calcium channels is well established, yet, sodium channels were regarded mainly as charge carriers. Many lines of evidence suggest a more fine-tuning role played by sodium channels. Using rat cerebrocortical isolated nerve endings (synaptosomes) and two toxins that have separate sites of action on sodium channels and provoke distinct changes in channel kinetics, we were able to show that depending on the rate of increase in channel conductance, the outcome in terms of neurotransmitter release and calcium channel types coupled to that event are different. Mainly, our study focused on veratridine, an alkaloid from lilaceous plants that binds to sodium channel toxin site 2, and tityustoxin, a toxin purified from the venom of the Brazilian yellow scorpion Tityus serrulatus that binds to site 3. Veratridine induces a slower increase in intrasynaptosomal sodium and calcium concentrations, slower depolarization, delayed exocytosis and a slower and predominantly calcium-independent glutamate release, when compared to tityustoxin.Thus, we have used these two toxins to investigate the events that start with sodium entry and culminate with the release of glutamate in isolated nerve endings (synaptosomes) from rat cerebral cortex. With that in mind we measured intrasynaptosomal free sodium concentration [Na(+)](i), intrasynaptosomal free calcium concentration [Ca(2+)](i), membrane potential, exocytosis and glutamate release using fluorescent probes.

Calcium entry through L-type calcium channels causes mitochondrial disruption and chromaffin cell death

Sustained, mild K+ depolarization caused bovine chromaffin cell death through a Ca(2+)-dependent mechanism. During depolarization, Ca(2+) entered preferentially through L-channels to induce necrotic or apoptotic cell death, depending on the duration of the cytosolic Ca(2+) concentration ([Ca(2+)](c)) signal, as proven by the following. (i) The L-type Ca(2+) channel activators Bay K 8644 and FPL64176, more than doubled the cytotoxic effects of 30 mm K+; (ii) the L-type Ca(2+) channel blocker nimodipine suppressed the cytotoxic effects of K+ alone or K+ plus FPL64176; (iii) the potentiation by FPL64176 of the K+ -evoked [Ca(2+)](c) elevation was totally suppressed by nimodipine. Cell exposure to K+ plus the L-type calcium channel agonist FPL64176 caused an initial peak rise followed by a sustained elevation of the [Ca(2+)](c) that, in turn, increased [Ca(2+)](m) and caused mitochondrial membrane depolarization. Cyclosporin A, a blocker of the mitochondrial transition pore, and superoxide dismutase prevented the apoptotic cell death induced by Ca(2+) overload through L-channels. These results suggest that Ca(2+) entry through L-channels causes both calcium overload and mitochondrial disruption that will lead to the release of mediators responsible for the activation of the apoptotic cascade and cell death. This predominant role of L-type Ca(2+) channels is not shared by other subtypes of high threshold voltage-dependent neuronal Ca(2+) channels (i.e. N, P/Q) expressed by bovine chromaffin cells.

Ba(2+)-induced chromaffin cell death: cytoprotection by Ca(2+) channel antagonists

Exposure of bovine adrenal medullary chromaffin cells to Ba(2+) ions (in the absence of Ca(2+) ions) caused their death, measured as lactate dehydrogenase (LDH) release. The concentration of Ba(2+) required to damage the cells by about 65% ranged between 1 and 10 mM (no Ca(2+) added); the required exposure time was rather brief (15 min-4 h). The simultaneous presence of Ca(2+), Mg(2+) or Zn(2+) together with Ba(2+) (2 mM, 4 h) afforded cyprotection (60-80%). Individual selective blockers of Ca(2+) channel subtypes afforded no protection. However, combined nifedipine (3 microM) plus omega-conotoxin MVIIC (3 microM) offered full protection. Substantial protection was also seen with the "wide-spectrum" Ca(2+) channel blockers penfluridol (0.3 microM), lubeluzole (3 microM), dotarizine (3 microM), flunarizine (3 microM), and mibefradil (3 microM). This protection was due to blockade of Ba(2+) entry through Ca(2+) channels because dotarizine (10 microM) inhibited the increase in cytosolic [Ba(2+)] seen in fura-2-loaded chromaffin cells. Once Ba(2+) accumulated in the cytosol, it was not extruded by the Na(+)/Ca(2+) exchanger, as shown by the prolonged and sustained elevation of the fura-2 signal. This contrasts with the fast dissipation of the fura-2 signal generated by [Ca(2+)](i) elevation. Thus, Ba(2+) overload can cause cell death by mechanisms similar to those reported for Ca(2+) overload and might be used as a novel and convenient tool to search for new cytoprotective compounds.

Veratridine induces apoptotic death in bovine chromaffin cells through superoxide production

The molecular mechanisms involved in veratridine-induced chromaffin cell death have been explored. We have found that exposure to veratridine (30 microM, 1 h) produces a delayed cellular death that reaches 55% of the cells 24 h after veratridine exposure. This death has the features of apoptosis as DNA fragmentation can be observed. Calcium ions play an important role in veratridine-induced chromaffin cell death because the cell permeant Ca(2+) chelator BAPTA-AM and extracellular Ca(2+) removal completely prevented veratridine-induced toxicity. Following veratridine treatment, there is a decrease in mitochondrial function and an increase in superoxide anion production. Veratridine-induced increase in superoxide production was blocked by tetrodotoxin (TTX; 10 microM), extracellular Ca(2+) removal and the mitochondrial permeability transition pore blocker cyclosporine A (10 microM). Veratridine-induced death was prevented by different antioxidant treatments including catalase (100 IU ml(-1)), N-acetyl cysteine (100 microM), allopurinol (100 microM) or vitamin E (50 microM). Veratridine-induced DNA fragmentation was prevented by TTX (10 microM). Veratridine produced a time-dependent increase in caspase activity that was prevented by Ca(2+) removal and TTX (10 microM). In addition, calpain and caspases inhibitors partially prevented veratridine-induced death. These results indicate that chromaffin cells share with neurons the molecular machinery involved in apoptotic death and might be considered a good model to study neuronal death during neurodegeneration.

Role of sodium ion influx in depolarization-induced neuronal cell death by high KCI or veratridine

Intracellular Na+ concentration plays an important role in the regulation of cellular energy metabolism; i.e., increased intracellular Na+ concentration stimulates glucose utilization both in cultured neurons and astrocytes. Both high KCI and veratridine, which have been known to cause neuronal damage, elicit increased glucose utilization, presumably via increased intracellular Na+ concentration. In the present study, we examined the role of intracellular Na+ influx in the mechanisms of neuronal cell damage induced by high KCl or veratridine assayed by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) colorimetric method. Rat primary cultures of striatal neurons were incubated with high KCl (final concentrations: 25, 50 mM) or veratridine (0.1-100 microM) with or without various inhibitors. High KCl depolarizes cell membrane, thus, leading to Na+ influx through an activation of voltage-sensitive Na+ channels, while veratridine elicits Na+ influx by directly opening these channels. After 24-h incubation with elevated [K+]o or veratridine, glucose contents in the medium decreased significantly (approximately by 7 mM), but remained higher than 18 mM. High [K+]o reduced percent cell viability significantly (approximately 50% at 25 mM, approximately 40% at 50 mM [K+]o, P<0.01), but tetrodotoxin (100 nM) had no protective effect, indicating that Na+ influx was not essential to high K+ -induced cell death. DL-2-Amino-5-phosponovaleric acid (APV) (1 mM) completely blocked cell death induced by elevated [K+]o, while 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) (10 microM) did not. In contrast, veratridine (>10 microM) caused cell damage in a dose-dependent and tetrodotoxin-sensitive manner, but none of APV, CNQX, or bepridil (Na+ -Ca2+ exchanger blocker) had any protective effect. Nifedipine (50 approximately 100 microM), however, reduced percent cell damage induced by veratridine.

Mechanisms of spontaneous cytosolic Ca2+ transients in differentiated human neuronal cells

We have studied Ca2+ homeostasis in a unique model of human neurons, the NT2N cell, which differentiates from a human teratocarcinoma cell line, NTera2/C1.D1 by retinoic acid treatment. When perifused with Krebs-HEPES buffer containing 2.5 mM CaCl2, fura-2 loaded NT2N cells produced spontaneous cytosolic Ca2+ oscillations, or Ca2+ transients. These cytosolic Ca2+ transients were not blocked by antagonists of glutamate (6-cyano-7-nitroquinoxaline-2,3-dione and D(-)-2-amino-5-phosphonopentanoic acid) or muscarinic (atropine) receptors. Omission of extracellular Ca2+ completely abolished Ca2+ oscillations and decreased the average Ca2+ level from 106 +/- 14 nM to 59 +/- 8 nM. Addition of the L-type Ca2+ channel blocker nifedipine (1 or 10 microM) or of the N-type inhibitor omega-conotoxin GVIA (5 microM) significantly, although incompletely, suppressed Ca2+ oscillations, while omega-conotoxin MVIIC (5 microM), a selective antagonist of P- and Q-channels, had no effect. Ni2+, at 100 microM, a concentration selective for T-type channels, did not inhibit Ca2+ transients. Non-specific blockage of Ca2+ channels by higher concentrations of Ni2+ (2-5 mM) or Co2+ (1 mM) abolished Ca2+ oscillations completely. The endoplasmic reticulum Ca2+-ATPase inhibitor, thapsigargin (1 microM), slightly decreased Ca2+ oscillation frequency, and induced a small transitory increase in the average cytosolic Ca2+ concentration. The mRNAs of L- (alpha1D subunit) and N-type (alpha1B subunit) Ca2+ channel were present in NT2N cells, while that of a T-type Ca2+ channel (alpha1-subunit) was not present in the NT2N cells as shown by reverse transcription-polymerase chain reaction. In conclusion, NT2N neuronal cells generate cytosolic Ca2+ oscillations mainly by influx of extracellular Ca2+ through multiple channels, which include L- and N-type channels, and do not require activation of glutamate or muscarinic receptors.

Effects of the neuroprotectant lubeluzole on the cytotoxic actions of veratridine, barium, ouabain and 6-hydroxydopamine in chromaffin cells

1. Incubation of bovine adrenal chromaffin cells with veratridine (10-100 microM) during 24 h, caused a concentration-dependent release of the cytosolic lactate dehydrogenase (LDH) into the bathing medium, an indicator of cell death. Lubeluzole or its R(-) enantiomer, R91154, did not enhance LDH release. Both lubeluzole and R91154 (0.3-10 microM) decreased the veratridine-induced LDH release. 2. Penfluridol did not increase LDH release at concentrations 0.003-1 microM; 3-10 microM increased LDH release to 50-60%, after 24 h exposure. Penfluridol (0.03-0.3 microM) did not protect against the cytotoxic effects of veratridine; at 1 microM, 15% protection was produced. Higher concentrations (3-10 microM) enhanced the cytotoxic effects of veratridine. 3. Ba2+ ions caused a concentration-dependent increase of LDH release. This cytotoxic effect was partially prevented by 3 microM lubeluzole and fully counteracted by 1 microM penfluridol. R91154 was less potent than lubeluzole and only protected against the lesion induced by 0.5 mM Ba2+. 4. Ouabain (10 microM during 24 h) increased LDH release to about 30%. Both lubeluzole (0.3-10 microM) and the lower concentrations of penfluridol (0.003-0.3 microM) prevented the ouabain cytotoxic effects. At higher concentrations (3 microM), penfluridol increased drastically the ouabain cytotoxic effects. 5. 6-Hydroxydopamine (6-OHDA) caused significant cytotoxic effects at 30 and 100 microM. Lubeluzole (3-10 microM) or penfluridol (0.03-0.3 microM) had no cytoprotective effects against 6-OHDA. 6. Lubeluzole (3 microM), R91154 (3 microM) and penfluridol (1 microM) blocked the current through Na+ channels in voltage-clamped chromaffin cells (I(Na)) by around 20-30%. Ca2+ current through Ca2+ channels (I(Ca)) was inhibited 57% by lubeluzole and R91154 and 50% by penfluridol. The effects of penfluridol were not washed out, but those of lubeluzole and R91154 were readily reversible. 7. Lubeluzole (3 microM) induced reversible blockade of the oscillations of the cytosolic Ca2+, [Ca2+]i, in fura-2-loaded cells exposed to 30 or 100 microM veratridine. Penfluridol (1 microM) inhibited those oscillations in an irreversible manner. 8. The results suggest that lubeluzole and its R-isomer caused cytoprotection against veratridine cell damage, by blocking the veratridine stimulated Na+ and Ca2+ entry, as well as the [Ca2+]i oscillations. The Ba2+ and ouabain cytotoxic effects were prevented more efficiently by penfluridol, likely by blocking the plasmalemmal Na+/Ca2+ exchanger. It remains dubious whether these findings are relevant to the reported neuroprotective action of lubeluzole in stroke; the doubt rests in the stereoselective protecting effects of lubeluzole in in vivo stroke models, as opposed to its lack of stereoselectivity in the in vitro model reported here.

Differential effects of the neuroprotectant lubeluzole on bovine and mouse chromaffin cell calcium channel subtypes

1. The effects of lubeluzole (a neuroprotective benzothiazole derivative) and its (-) enantiomer R91154 on whole-cell currents through Ca2+ channels, with 10 mM Ba2+ as charge carrier (IBa), have been studied in bovine and mouse voltage-clamped adrenal chromaffin cells. Currents generated by applying 50 ms depolarizing test pulses to 0 mV, from a holding potential of -80 mV, at 10 s intervals had an average magnitude of 1 nA. 2. Lubeluzole and R91154 blocked the peak IBa of bovine chromaffin cells in a time and concentration-dependent manner; their IC50s were 1.94 microM for lubeluzole and 2.54 microM for R91154. In a current-voltage protocol, lubeluzole (3 microM) inhibited peak IBa at all test potentials. However, no obvious shifts of the I-V curve were detected. 3. After 10 min exposure to 3 microM lubeluzole, the late current (measured at the end of the pulse) was inhibited more than the peak current. Upon wash out of the drug, the inactivation reversed first and then the peak current recovered. 4. Blockade of peak current was greater at more depolarizing holding potentials (i.e. 35% at -110 mV and 87% at -50 mV, after 10 min superfusion with lubeluzole). Inactivation of the current was pronounced at -110 mV, decreased at -80 mV and did not occur at -50 mV. 5. Intracellular dialysis of bovine voltage-clamped chromaffin cells with 3 microM lubeluzole caused neither blockade nor inactivation of IBa. The external application of 3 microM lubeluzole to those dialysed cells produced inhibition as well as inactivation of IBa. 6. The effects of lubeluzole (3 microM) on IBa in mouse chromaffin cells were similar to those in bovine chromaffin cells. At -80 mV holding potential, a pronounced inactivation of the current led to greater blockade of the late IBa (66%) as compared with peak IBa (46% after 10 min superfusion with lubeluzole). 7. In mouse chromaffin cells approximately half of the whole-cell IBa was sensitive to 3 microM nifedipine (L-type Ca2+ channels) and the other half to 3 microM omega-conotoxin MVIIC (non-L-type Ca2+ channels). In omega-conotoxin MVIIC-treated cells, 3 microM lubeluzole caused little blockade and inactivation of IBa. However in nifedipine-treated cells, lubeluzole caused a pronounced blockade and inactivation of IBa that reversed upon wash out of the compound. 8. The results are compatible with the idea that lubeluzole preferentially blocks non-L-types of voltage-dependent Ca2+ channels expressed by bovine and mouse chromaffin cells. The higher concentrations of the compound also block L-type Ca2+ channels. The mechanism of inhibition involves the access of lubeluzole to the open channel from the outside of the cell and promotion of its inactivation. The differential blockade of Ca2+ channel subtypes might contribute to the neuroprotective actions of lubeluzole (which exhibit stereoselectivity). However, in view of the lack of stereoselectivity in blocking Ca2+ channels, this effect cannot be the only explanation for the protective activity of lubeluzole in stroke.

'Wide-spectrum Ca2+ channel antagonists': lipophilicity, inhibition, and recovery of secretion in chromaffin cells

Repetitive application of short depolarizing K+ pulses (70 mM K+, 2 mM Ca2+ Krebs-HEPES solution, for 10 s every 5 min) produced reproducible catecholamine secretory responses from superfused bovine chromaffin cells. At 10 microM for 15 min, the piperazine derivatives dotarizine, flunarizine and lidoflazine inhibited secretion by around 90%; cinnarizine halved the secretory response. Recovery of secretion after 30-min washout with Krebs-HEPES solution amounted to 75% in the case of dotarizine, 8% for flunarizine, 46% for lidoflazine and 21% for cinnarizine. The benzothiazol derivatives (10 microM) (+)-S-lubeluzole and R91154 (the (-)-R-enantiomer of lubeluzole) blocked the response by 75%; sabeluzole inhibited secretion by only 34% and R56865 (N-[1-(4-(4-fluorophenoxy)butyl]-4-piperidinyl-N-methyl-2-benzo-thiaz olamine) by 61%. Recoveries were around 70% in the case of these four benzothiazol derivatives. The diphenylbutyl-piperazine derivatives fluspirilene and penfluridol inhibited secretion by over 80%; no recovery was produced after 30-min washout. The inhibition of secretion was time dependent, as the recovery of the response was. Blockade of secretion by dotarizine and flunarizine occurred even in the absence of intermittent K+ stimulations of the cells. No obvious correlation was seen between the octanol/water partition coefficients of the ten compounds tested (that ranged between 6 and 4.61), the rate and extent of blockade of secretion, and the recovery of the secretory response upon washout. Rather than non-specific actions on ion channels (and secretion) due to their high lipophilicity, we believe that blockade of various Ca2+ channels relates to their binding properties to specific channel micro and macrodomains, as the case might be for 'narrow' (omega-conotoxin GVIA) and 'wide-spectrum' (omega-conotoxin MVIIC) peptide toxins.

Identification of calcium channels involved in neuronal injury in rat hippocampal slices subjected to oxygen and glucose deprivation

The presynaptic Ca2+-influx affecting glutamate release during neuropathological processes is mediated via voltage-sensitive calcium channels (VSCCs). There is controversy, however, over the fractional contribution of the specific channel types involved. We have addressed this by investigating the protective effects of various VSCC blockers on oxygen and glucose-deprived rat hippocampal slices. The viability of treated and non-treated slices was assayed electrophysiologically by measuring the evoked population spike (PS) amplitude in the stratum pyramidale of the CA1 region and by imaging slices loaded with fluorochrome dyes specific for dead (ethidium homodimer) and live (calcein) cells using confocal microscopy. PS amplitudes were significantly (P < 0.01) depressed from 4.4 +/- 0.2 mV (n = 38) to 0.2 +/- 0.1 mV (n = 40) after the deprivation insult. Responses from deprived slices treated with omega-conotoxin MVIIC (100 nM; 4.2 +/- 0.5 mV; n = 20) were not significantly different from control, non-deprived slice responses. In contrast, deprived slices treated with either L-type (0.1 or 1 microM nimodipine) or N-type (0.1 or 3 microM omega-conotoxin MVIIA) blockers showed no significant protection. The viability of CA1 neurons as revealed by the fluorescence live/dead confocal viability assay was consistent with the electrophysiological measurements. By comparison with previous studies using P- and Q-type blockers to attempt neuroprotection against the same deprivation insult, the rank order in which specific Ca2+-channel types contribute to neuronal death due to oxygen and glucose deprivation was determined to be Q > N >> P > L.