Extracellular ATP-Induced Alterations in Extracellular H+ Fluxes From Cultured Cortical and Hippocampal Astrocytes

Small alterations in the level of extracellular H⁺ can profoundly alter neuronal activity throughout the nervous system. In this study, self-referencing H⁺-selective microelectrodes were used to examine extracellular H⁺ fluxes from individual astrocytes. Activation of astrocytes cultured from mouse hippocampus and rat cortex with extracellular ATP produced a pronounced increase in extracellular H⁺ flux. The ATP-elicited increase in H⁺ flux appeared to be independent of bicarbonate transport, as ATP increased H⁺ flux regardless of whether the primary extracellular pH buffer was 26 mM bicarbonate or 1 mM HEPES, and persisted when atmospheric levels of CO₂ were replaced by oxygen. Adenosine failed to elicit any change in extracellular H⁺ fluxes, and ATP-mediated increases in H⁺ flux were inhibited by the P2 inhibitors suramin and PPADS suggesting direct activation of ATP receptors. Extracellular ATP also induced an intracellular rise in calcium in cultured astrocytes, and ATP-induced rises in both calcium and H⁺ efflux were significantly attenuated when calcium re-loading into the endoplasmic reticulum was inhibited by thapsigargin. Replacement of extracellular sodium with choline did not significantly reduce the size of the ATP-induced increases in H⁺ flux, and the increases in H⁺ flux were not significantly affected by addition of EIPA, suggesting little involvement of Na⁺/H⁺ exchangers in ATP-elicited increases in H⁺ flux. Given the high sensitivity of voltage-sensitive calcium channels on neurons to small changes in levels of free H⁺, we hypothesize that the ATP-mediated extrusion of H⁺ from astrocytes may play a key role in regulating signaling at synapses within the nervous system.

ATP-mediated increase in H+ flux from retinal Müller cells: a role for Na+/H+ exchange

Small alterations in extracellular H⁺ can profoundly alter neurotransmitter release by neurons. We examined mechanisms by which extracellular ATP induces an extracellular H⁺ flux from Müller glial cells, which surround synaptic connections throughout the vertebrate retina. Müller glia were isolated from tiger salamander retinae and H⁺ fluxes examined using self-referencing H⁺-selective microelectrodes. Experiments were performed in 1 mM HEPES with no bicarbonate present. Replacement of extracellular sodium by choline decreased H⁺ efflux induced by 10 µM ATP by 75%. ATP-induced H⁺ efflux was also reduced by Na⁺/H⁺ exchange inhibitors. Amiloride reduced H⁺ efflux initiated by 10 µM ATP by 60%, while 10 µM cariporide decreased H⁺ flux by 37%, and 25 µM zoniporide reduced H⁺ flux by 32%. ATP-induced H⁺ fluxes were not significantly altered by the K⁺/H⁺ pump blockers SCH28080 or TAK438, and replacement of all extracellular chloride with gluconate was without effect on H⁺ fluxes. Recordings of ATP-induced H⁺ efflux from cells that were simultaneously whole cell voltage clamped revealed no effect of membrane potential from -70 mV to 0 mV. Restoration of extracellular potassium after cells were bathed in 0 mM potassium produced a transient alteration in ATP-dependent H⁺ efflux. The transient response to extracellular potassium occurred only when extracellular sodium was present and was abolished by 1 mM ouabain, suggesting that alterations in sodium gradients were mediated by Na⁺/K⁺-ATPase activity. Our data indicate that the majority of H⁺ efflux elicited by extracellular ATP from isolated Müller cells is mediated by Na⁺/H⁺ exchange.NEW & NOTEWORTHY Glial cells are known to regulate neuronal activity, but the exact mechanism(s) whereby these "support" cells modulate synaptic transmission remains unclear. Small changes in extracellular levels of acidity are known to be particularly powerful regulators of neurotransmitter release. Here, we show that extracellular ATP, known to be a potent activator of glial cells, induces H⁺ efflux from retinal Müller (glial) cells and that the bulk of the H⁺ efflux is mediated by Na⁺/H⁺ exchange.

Medium-retaining Petri dish insert to grow and image cultured cells

BACKGROUND

Microscope chambers that accept glass coverslips with cultured cells are often used to monitor intracellular Ca²⁺ concentration ([Ca²⁺]_i) during cell superfusion. Unfortunately, the experimental maneuvers associated with the coverslip installation in these chambers (medium removal and re-application) trigger unintended [Ca²⁺]_i elevations.

NEW METHOD

To prevent these [Ca²⁺]_i elevations, a Petri dish insert has been constructed. The insert features a superfusion-optimized well to grow cell cultures. After this insert is removed from the Petri dish, the well retains the medium. This feature allows the inserts to be installed in microscope chambers while keeping the cells submerged at all times.

RESULTS

These inserts were used to test the impact of a transient medium removal from the well (an equivalent of a coverslip removal from the medium) on [Ca²⁺]_i in primary murine cortical neurons and astrocytes, and in HEK-293 cells. In all of these models, the medium removal/re-application caused a micromolar [Ca²⁺]_i spike. While in neurons this spike was caused by a Ca²⁺ influx, in astrocytes and HEK-293 cells, it was caused by a Ca²⁺ release from intracellular stores. After the spike, a subpopulation of neurons failed to restore low [Ca²⁺]_i; in 24% of the astrocytes, the spike triggered [Ca²⁺]_i oscillations. However, prior to the spike, [Ca²⁺]_i was low and uniform in all these cells.

COMPARISON WITH EXISTING METHOD(S)

The new method avoids the artificially-induced [Ca²⁺]_i elevations that take place during the handling of glass coverslips with cultured cells.

CONCLUSIONS

The new method allows monitoring [Ca²⁺]_i without disturbing the basal [Ca²⁺]_i levels.

Visualizing Metal Content and Intracellular Distribution in Primary Hippocampal Neurons with Synchrotron X-Ray Fluorescence

Increasing evidence suggests that metal dyshomeostasis plays an important role in human neurodegenerative diseases. Although distinctive metal distributions are described for mature hippocampus and cortex, much less is known about metal levels and intracellular distribution in individual hippocampal neuronal somata. To solve this problem, we conducted quantitative metal analyses utilizing synchrotron radiation X-Ray fluorescence on frozen hydrated primary cultured neurons derived from rat embryonic cortex (CTX) and two regions of the hippocampus: dentate gyrus (DG) and CA1. Comparing average metal contents showed that the most abundant metals were calcium, iron, and zinc, whereas metals such as copper and manganese were less than 10% of zinc. Average metal contents were generally similar when compared across neurons cultured from CTX, DG, and CA1, except for manganese that was larger in CA1. However, each metal showed a characteristic spatial distribution in individual neuronal somata. Zinc was uniformly distributed throughout the cytosol, with no evidence for the existence of previously identified zinc-enriched organelles, zincosomes. Calcium showed a peri-nuclear distribution consistent with accumulation in endoplasmic reticulum and/or mitochondria. Iron showed 2-3 distinct highly concentrated puncta only in peri-nuclear locations. Notwithstanding the small sample size, these analyses demonstrate that primary cultured neurons show characteristic metal signatures. The iron puncta probably represent iron-accumulating organelles, siderosomes. Thus, the metal distributions observed in mature brain structures are likely the result of both intrinsic neuronal factors that control cellular metal content and extrinsic factors related to the synaptic organization, function, and contacts formed and maintained in each region.

Neuronal acid-induced [Zn²⁺]i elevations calibrated using the low-affinity ratiometric probe FuraZin-1

The experiments were carried out on primary cultures of murine cortical neurons from cryopreserved preparations obtained from embryonic-day-16 fetuses. To calibrate acid-induced intracelluar [Zn(2+) ] ([Zn(2+) ]i ) elevations, a low affinity (Kd = 39 μM at pH 6.1) ratiometric Zn(2+) probe, FuraZin-1, was used. A pHi drop from 7.2 to 6.1 caused [Zn(2+) ]i elevations reaching 2 μM; when the thiol-reactive agent N-ethylmaleimide (NEM) was subsequently applied, [Zn(2+) ]i increased further to 5.6 μM; analogous acid- and NEM-induced [Zn(2+) ]i elevations could also be detected but not calibrated, using the high affinity Zn(2+) probe FluoZin-3. The data indicate that NEM causes Zn(2+) release from ligands that chelate Zn(2+) at pH 6.1. ATP could also chelate Zn(2+) at pH 6.1 because its pKa is about 6.8. Therefore, it was tested whether an ATP depletion affects the acid-induced [Zn(2+) ]i elevations. The ATP depletion was induced by inhibiting mitochondrial and glycolytic ATP production. Interestingly, an almost complete ATP depletion (confirmed using a luciferin/luciferase assay) failed to affect the acid-induced [Zn(2+) ]i increases. These data suggest that the total amount of Zn(2+) accumulated in intracellular ATP-dependent stores (Zn(2+) -ATP complexes and organelles that accumulate Zn(2+) in an ATP-dependent manner) is negligible compared to the amount of Zn(2+) accumulated in the acid-sensitive intracellular ligands. In vitro, upon acidification, Zn(2+) -cysteine complexes release Zn(2+) and ATP chelates the released Zn(2+) . However, in vivo (cultured neurons), an ATP depletion failed to enhance acid-induced [Zn(2+) ]i elevations. These [Zn(2+) ]i elevations were calibrated using a low affinity ratiometric probe FuraZin-1; they reached 2 µM levels and increased to 5 µM when a thiol-reactive agent, N-ethylmaleimide, compromised Zn(2+) binding by cysteines.

Proton-dependent zinc release from intracellular ligands

In cultured cortical and hippocampal neurons when intracellular pH drops from 6.6 to 6.1, yet unclear intracellular stores release micromolar amounts of Zn(2+) into the cytosol. Mitochondria, acidic organelles, and/or intracellular ligands could release this Zn(2+) . Although exposure to the protonophore FCCP precludes reloading of the mitochondria and acidic organelles with Zn(2+) , FCCP failed to compromise the ability of the intracellular stores to repeatedly release Zn(2+) . Therefore, Zn(2+) -releasing stores were not mitochondria or acidic organelles but rather intracellular Zn(2+) ligands. To test which ligands might be involved, the rate of acid-induced Zn(2+) release from complexes with cysteine, glutathione, histidine, aspartate, glutamate, glycine, and carnosine was investigated; [Zn(2+) ] was monitored in vitro using the ratiometric Zn(2+) -sensitive fluorescent probe FuraZin-1. Carnosine failed to chelate Zn(2+) but did chelate Cu(2+) ; the remaining ligands chelated Zn(2+) and upon acidification were releasing it into the medium. However, when pH was decreasing from 6.6 to 6.1, only zinc-cysteine complexes rapidly accelerated the rate of Zn(2+) release. The zinc-cysteine complexes also released Zn(2+) when a histidine-modifying agent, diethylpyrocarbonate, was applied at pH 7.2. Since the cytosolic zinc-cysteine complexes can contain micromolar amounts of Zn(2+) , these complexes may represent the stores responsible for an acid-induced intracellular Zn(2+) release. This study aimed at identifying intracellular stores which release Zn(2+) when pHi drops from 6.6 to 6.1. It was found that these stores are not mitochondria or acidic organelles, but rather intracellular Zn(2+) ligands. When the pH was decreasing from 6.6 to 6.1, only zinc-cysteine complexes showed a rapid acceleration in the rate of Zn(2+) release. Therefore, the stores responsible for an acid-induced intracellular Zn(2+) release in neurons may be the cytosolic zinc-cysteine complexes.

Cytosolic acidification and intracellular zinc release in hippocampal neurons

In neurons exposed to glutamate, Ca²⁺ influx triggers intracellular Zn²⁺ release via an as yet unclear mechanism. As glutamate induces a Ca²⁺-dependent cytosolic acidification, the present work tested the relationships among intracellular Ca²⁺ concentration ([Ca²⁺](i)), intracellular pH (pH(i) ), and [Zn²⁺](i). Cultured hippocampal neurons were exposed to glutamate and glycine (Glu/Gly), while [Zn²⁺](i), [Ca²⁺](i) and pH(i) were monitored using FluoZin-3, Fura2-FF, and 2',7'-bis-(2-carboxyethyl)-5(6)-carboxyfluorescein, respectively. Glu/Gly applications decreased pH(i) to 6.1 and induced intracellular Zn²⁺ release in a Ca²⁺-dependent manner, as expected. The pH(i) drop reduced the affinity of FluoZin-3 and Fura-2-FF for Zn²⁺. The rate of Glu/Gly-induced [Zn²⁺](i) increase was not correlated with the rate of [Ca²⁺](i) increase. Instead, the extent of [Zn²⁺](i) elevations corresponded well to the rate of pH(i) drop. Namely, [Zn²⁺](i) increased more in more highly acidified neurons. Inhibiting the mechanisms responsible for the Ca²⁺-dependent pH(i) drop (plasmalemmal Ca²⁺ pump and mitochondria) counteracted the Glu/Gly-induced intracellular Zn²⁺ release. Alkaline pH (8.5) suppressed Glu/Gly-induced intracellular Zn²⁺ release whereas acidic pH (6.0) enhanced it. A pH(i) drop to 6.0 (without any Ca²⁺ influx or glutamate receptor activation) led to intracellular Zn²⁺ release; the released Zn²⁺ (free Zn²⁺ plus Zn²⁺) bound to Fura-2FF and FluoZin-3) reached 1 μM.

Cytosolic zinc release and clearance in hippocampal neurons exposed to glutamate--the role of pH and sodium

Although Zn(2+) homeostasis in neurons is tightly regulated and its destabilization has been linked to a number of pathologies including Alzheimer's disease and ischemic neuronal death, the primary mechanisms affecting intracellular Zn(2+) concentration ([Zn(2+) ](i)) in neurons exposed to excitotoxic stimuli remain poorly understood. The present work addressed these mechanisms in cultured hippocampal neurons exposed to glutamate and glycine (Glu/Gly). [Zn(2+)](i) and intracellular Ca(2+) concentration were monitored simultaneously using FluoZin-3 and Fura-2FF, and intracellular pH (pH(i)) was studied in parallel experiments using 2',7'-bis-(2-carboxyethyl)-5(6)-carboxyfluorescein. Glu/Gly applications under Na(+)-free conditions (Na(+) substituted with N-methyl-D-glucamine(+)) caused Ca(2+) influx, pH(i) drop, and Zn(2+) release from intracellular stores. Experimental maneuvers resulting in a pH(i) increase during Glu/Gly applications, such as stimulation of Na(+) -dependent pathways of H(+) efflux, forcing H(+) efflux via gramicidin-formed channels, or increasing extracellular pH counteracted [Zn(2+)](i) elevations. In the absence of Na(+), the rate of [Zn(2+)](i) decrease could be correlated with the rate of pH(i) increase. In the presence of Na(+), the rate of [Zn(2+) ](i) decrease was about twice as fast as expected from the rate of pH(i) elevation. The data suggest that Glu/Gly-induced cytosolic acidification promotes [Zn(2+) ](i) elevations and that Na(+) counteracts the latter by promoting pH(i)-dependent and pH(i)-independent mechanisms of cytosolic Zn(2+) clearance.

Contribution of Na(+)/Ca(2+) exchange to excessive Ca(2+) loading in dendrites and somata of CA1 neurons in acute slice

Multiple Ca(2+) entry routes have been implicated in excitotoxic Ca(2+) loading in neurons and reverse-operation of sodium-calcium exchangers (NCX) has been shown to contribute under conditions where intracellular Na(+) levels are enhanced. We have investigated effects of KB-R7943, an inhibitor of reverse-operation NCX activity, on Ca(2+) elevations in single CA1 neurons in acute hippocampal slices. KB-R7943 had no significant effect on input resistance, action potential waveform, or action potential frequency adaptation, but reduced L-type Ca(2+) entry in somata. Nimodipine was therefore included in subsequent experiments to prevent complication from effects of L-type influx on evaluation of NCX activity. NMDA produced transient primary Ca(2+) increases, followed by propagating secondary Ca(2+) increases that initiated in apical dendrites. KB-R7943 had no significant effect on primary or secondary Ca(2+) increases generated by NMDA. The Na(+)/K(+) ATPase inhibitor ouabain (30 microM) produced degenerative Ca(2+) overload that was initiated in basal dendrites. KB-R7943 significantly reduced initial Ca(2+) increases and delayed the propagation of degenerative Ca(2+) loads triggered by ouabain, raising the possibility that excessive intracellular Na(+) loading can trigger reverse-operation NCX activity. A combination of NMDA and ouabain produced more rapid Ca(2+) overload, that was contributed to by NCX activity. These results suggest that degenerative Ca(2+) signaling can be triggered by NMDA in dendrites, before intracellular Na(+) levels become sufficient to reverse NCX activity. However, since Na(+)/K(+) ATPase inhibition does appear to produce significant reverse-operation NCX activity, this additional Ca(2+) influx pathway may operate in ATP-deprived CA1 neurons and play a role in ischemic neurodegeneration.

AMPA-mediated excitotoxicity in oligodendrocytes: role for Na(+)-K(+)-Cl(-) co-transport and reversal of Na(+)/Ca(2+) exchanger

We investigated the role of Na(+)-K(+)-Cl(-) co-transporter isoform 1 (NKCC1) and reversal of Na(+)/Ca(2+) exchanger (NCX(rev)) in glutamate-mediated excitotoxicity in oligodendrocytes obtained from rat spinal cords (postnatal day 6-8). An immunocytochemical characterization showed that these cultures express NKCC1 and Na(+)/Ca(2+) exchanger isoforms 1, 2, and 3 (NCX1, NCX2, NCX3). Exposing the cultures to alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) plus cyclothiazide (CTZ) led to a transient rise in intracellular (), which was followed by a sustained overload, NKCC1 phosphorylation, and a NKCC1-mediated Na(+) influx. In the presence of a specific AMPA receptor inhibitor 6-cyano-7-nitroquinoxaline-2, 3-dione (CNQX), the AMPA/CTZ failed to elicit any changes in . The AMPA/CTZ-induced sustained rise led to mitochondrial Ca(2+) accumulation, release of cytochrome c from mitochondria, and cell death. The AMPA/CTZ-elicited increase, mitochondrial damage, and cell death were significantly reduced by inhibiting NKCC1 or NCX(rev). These data suggest that in cultured oligodendrocytes, activation of AMPA receptors leads to NKCC1 phosphorylation that enhances NKCC1-mediated Na(+) influx. The latter triggers NCX(rev) and NCX(rev)-mediated overload and compromises mitochondrial function and cellular viability.

NCX and NCKX Operation in Ischemic Neurons

Within the first 2 min of global brain ischemia, extracellular [K+] ([K+]o) increases above 60 mM and [Na+](o) drops to about 50 mM, indicating a massive K+ efflux and Na+ influx, a phenomenon known as anoxic depolarization (AD). Similar ionic shifts take place during repetitive peri-infarct depolarizations (PID) in the area penumbra in focal brain ischemia. The size of ischemic infarct is determined by the duration of AD and PID. However, the mechanism of cytosolic [Ca2+] ([Ca2+]c) elevation during AD or PID is poorly understood. Our data show that the exposure of cultured rat hippocampal CA1 neurons to AD-like conditions promptly elevates [Ca2+]c to about 30 microM. These high [Ca2+]c elevations depend on external Ca2+ and can be prevented by removing Na+ or by simultaneously inhibiting NMDA and AMPA/kainate receptors. These data indicate that [Ca2+]c elevations during AD result from Na+ influx via either NMDA or AMPA/kainate channels. The mechanism of the Na-dependent [Ca2+]c elevations may involve a reversal of plasmalemmal Na+/Ca2+ (NCX) and/or Na+/Ca2+ + K+ (NCKX) exchangers. KB-R7943, an NCX inhibitor, suppresses a fraction of the Na-dependent Ca2+ influx during AD. Therefore, Ca2+ influx via NCX and a KB-R7943-resistant pathway (possibly NCKX) is involved. Inhibition of the Na-dependent Ca2+ influx is likely to decrease ischemic brain damage. No drugs are known that are able to inhibit the KB-R7943-resistant component of Na-dependent Ca2+ influx during AD. The present data encourage development of such agents as potential therapeutic means to limit ischemic brain damage after stroke or heart attack.

Critical role of sodium in cytosolic [Ca2+] elevations in cultured hippocampal CA1 neurons during anoxic depolarization

Although the extent of ischemic brain damage is directly proportional to the duration of anoxic depolarization (AD), the mechanism of cytosolic [Ca(2+)] ([Ca(2+)](c)) elevation during AD is poorly understood. To address the mechanism in this study, [Ca(2+)](c) was monitored in cultured rat hippocampal CA1 neurons loaded with a Ca-sensitive dye, fura-2FF, and exposed to an AD-simulating medium containing (in mmol/L): K(+) 65, Na(+) 50, Ca(2+) 0.13, glutamate 0.1, and pH reduced to 6.6. Application of this medium promptly elevated [Ca(2+)](c) to about 30 micromol/L, but only if oxygen was removed, the respiratory chain was inhibited, or if the mitochondria were uncoupled. These high [Ca(2+)](c) elevations depended on external Ca(2+) and could not be prevented by inhibiting NMDA or alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA)/kainate receptors, or gadolinium-sensitive channels. However, they could be prevented by removing external Na(+) or simultaneously inhibiting NMDA and AMPA/kainate receptors; 2-[2-[4-(4-nitrobenzyloxy)phenyl]ethyl]isothiourea methanesulfonate (KB-R7943), an inhibitor of plasmalemmal Na(+)/Ca(2+) exchanger, partly suppressed them. The data indicate that the [Ca(2+)](c) elevations to 30 micromol/L during AD result from Na(+) influx. Activation of either NMDA or AMPA/kainate channels provides adequate Na(+) influx to induce these [Ca(2+)](c) elevations, which are mediated by KB-R7943-sensitive and KB-R7943-resistant mechanisms.

Unconventional neuroprotection against Ca2+ -dependent insults by metalloporphyrin catalytic antioxidants

We evaluated whether both inert and catalytically active metalloporphyrin antioxidants, meso-substituted with either phenyl-based or N-alkylpyridinium-based groups, suppress Ca(2+)-dependent neurotoxicity in cell culture models of relevance to cerebral ischemia. Representatives from both metalloporphyrin classes, regardless of antioxidant strength, protected cultured cortical neurons or PC-12 cultures against the Ca(2+) ionophores ionomycin or A23187, by suppressing neurotoxic Ca(2+) influx. Some metalloporphyrins suppressed excitotoxic Ca(2+) influx indirectly induced by the Ca(2+) ionophores in cortical neurons. Metalloporphyrins did not quench intracellular fluorescence, suggesting localization to the plasma membrane interface and/or interference with Ca(2+) ionophores. Metalloporphyrins suppressed ionomycin-induced Mn(2+) influx, but did not protect cortical neurons against pyrithione, a Zn(2+) ionophore. In other Ca(2+)-dependent paradigms, Ca(2+) influx via plasma membrane depolarization, but not through reversal of plasmalemmal Na(+)/Ca(2+) exchangers, was modestly suppressed by Mn(III)meso-tetrakis(4-benzoic acid)porphyrin (Mn(III)TBAP) or by an inert analog, Zn(II)TBAP. Mn(III)TBAP and Zn(II)TBAP potently protected cortical neurons against long-duration oxygen-glucose deprivation (OGD), performed in the presence of antagonists of NMDA, alpha-amino-3-hydroxy-5-methylisoxazole-4-propionate and L-type voltage-gated Ca(2+) channels, raising the possibility of an unconventional mode of blockade of transient receptor protein melastatin 7 channels by a metalloTBAP family of metalloporphyrins. The present study extends the range of Ca(2+)-dependent insults for which metalloporphyrins demonstrate unconventional neuroprotection. MetalloTBAPs appear capable of targeting an OGD temporal continuum.

Importance of K+-dependent Na+/Ca2+-exchanger 2, NCKX2, in motor learning and memory

Plasma membrane Na+/Ca2+-exchangers play a predominant role in Ca2+ extrusion in brain. Neurons express several different Na+/Ca2+-exchangers belonging to both the K+-independent NCX family and the K+-dependent NCKX family. The unique contributions of each of these proteins to neuronal Ca2+ homeostasis and/or physiology remain largely unexplored. To address this question, we generated mice in which the gene encoding the abundant neuronal K+ -dependent Na+/Ca2+-exchanger protein, NCKX2, was knocked out. Analysis of these animals revealed a significant reduction in Ca2+ flux in cortical neurons, a profound loss of long term potentiation and an increase in long term depression at hippocampal Schaffer/CA1 synapses, and clear deficits in specific tests of motor learning and spatial working memory. Surprisingly, there was no obvious loss of photoreceptor function in cones, where expression of the NCKX2 protein had been reported previously. These data emphasize the critical and non-redundant role of NCKX2 in the local control of neuronal [Ca2+] that is essential for the development of synaptic plasticity associated with learning and memory.

Protection of ischemic rat spinal cord white matter: Dual action of KB-R7943 on Na+/Ca2+ exchange and L-type Ca2+ channels

The effect of the Na+/Ca(2+)-exchange inhibitor KB-R7943 was investigated in spinal cord dorsal column ischemia in vitro. Oxygen/glucose deprivation at 37 degrees C for 1 h causes severe injury even in the absence of external Ca2+. KB-R7943 was very protective in the presence and absence of external Ca2+ implicating mechanisms in addition to extracellular Ca2+ influx through Na+/Ca(2+)-exchange, such as activation of ryanodine receptors by L-type Ca2+ channels. Indeed, blockade of L-type Ca2+ by nimodipine confers a certain degree of protection of dorsal column against ischemia; combined application of nimodipine and KB-R7943 was not additive suggesting that KB-R7943 may also act on Ca2+ channels. KB-R7943 reduced inward Ba2+ current with IC50 = 7 microM in tsA-201 cells expressing Ca(v)1.2. Moreover, nifedipine and KB-R7943 both reduced depolarization-induced [Ca2+]i increases in forebrain neurons and effects were not additive. Nimodipine or KB-R7943 also reduced ischemic axoplasmic Ca2+ increase, which persisted in 0Ca2+/EGTA perfusate in dorsal column during ischemia. While KB-R7943 cannot be considered to be a specific Na+/Ca2+ exchange inhibitor, its profile makes it a very useful neuroprotectant in dorsal columns by: reducing Ca2+ import through reverse Na+/Ca2+ exchange; reducing influx through L-type Ca2+ channels, and indirectly inhibiting Ca2+ release from the ER through activation of ryanodine receptors.

High activity of K+-dependent plasmalemmal Na+/Ca2+ exchangers in hippocampal CA1 neurons

Ca(2+) influx via reversed K(+)-dependent (NCKX) and/or K(+)-independent (NCX) plasmalemmal Na(+)/Ca(2+) exchangers may play a role in neuronal death following global brain ischemia to which CA1 neurons are particularly vulnerable. Therefore, this work tested whether the rates of Ca(2+) influx via reversed NCKX or NCX in cultured rat CA1 neurons differ from those in forebrain neurons (FNs) or cerebellar granule cells (CGCs). The NCKX-mediated Ca(2+) influx was several times more rapid in CA1 neurons than in FNs or CGCs and was not affected by Na(+)/Ca(2+) exchange inhibitors, KB-R7943 or bepridil. NCKX reversal inhibitors are not yet available. Their development would greatly facilitate further testing the role of NCKX in ischemic death of CA1 neurons.

Differential contribution of plasmalemmal Na/Ca exchange isoforms to sodium-dependent calcium influx and NMDA excitotoxicity in depolarized neurons

Inhibition of Na(+),K(+)-ATPase during NMDA applications greatly increased NMDA-induced excitotoxicity in primary cultures of forebrain neurons (FNs), but not in cerebellar granule cells (CGCs). Because Na(+),K(+)-ATPase inhibition promotes reversal of plasmalemmal Na(+)/Ca(2+) exchangers, we compared the activities of reversed K(+)-independent (NCX) and K(+)-dependent (NCKX) Na(+)/Ca(2+) exchangers in these cultures. To this end, we measured gramicidin-induced and Na(+)-dependent elevation in cytosolic [Ca(2+)] ([Ca(2+)](c)) that represents Ca(2+) influx via reversed NCX and NCKX; NCX activity was dissected out by removing external K(+). The [Ca(2+)](c) elevations mediated by NCX alone, and NCX plus NCKX combined, were 17 and 6 times more rapid in FNs than in CGCs, respectively. Northern blot analysis showed that FNs preferentially express NCX1 whereas CGCs expressed NCX3. Differences in expression of other isoforms (NCX2, NCKX2, NCKX3 and NCKX4) were less pronounced. We tested whether the NCX or NCKX family of exchangers contributes most to the toxic NMDA-induced Ca(2+) influx in depolarized neurons. We found that in FNs, inhibition of NCX alone was sufficient to significantly limit NMDA excitotoxicity, whereas in CGCs, inhibition of both NCX and NCKX was required. The data suggest that the high activity of NCX isoforms expressed in FNs, possibly NCX1, sensitizes these neurons to NMDA excitotoxicity.

Inhibition of plasmalemmal Na(+)/Ca(2+) exchange by mitochondrial Na(+)/Ca(2+) exchange inhibitor 7-chloro-5-(2-chlorophenyl)-1,5-dihydro-4,1-benzothiazepin-2(3H)-one (CGP-37157) in cerebellar granule cells

In the heart, 7-chloro-5-(2-chlorophenyl)-1,5-dihydro-4,1-benzothiazepin-2(3H)-one (CGP-37157) inhibits mitochondrial but not sarcolemmal Na(+)/Ca(2+) exchange. Therefore, CGP-37157 is often used as an experimental tool to study the role of mitochondrial Na(+)/Ca(2+) exchange in Ca(2+) homeostasis in various cells, including neurons. However, neurons express several K(+)-dependent (NCKX) and/or K(+)-independent (NCX) isoforms of plasmalemmal Na(+)/Ca(2+) exchange not expressed in the sarcolemma. Because it has never been determined whether CGP-37157 inhibits plasmalemmal NCKX and/or NCX isoforms in neurons, we tested this possibility. As an index of NCKX and/or NCX activity, we studied Na-dependent and gramicidin-induced 45Ca(2+) accumulation in the presence and absence of K(+), respectively. In primary cultures of cerebellar granule cells, CGP-37157 with IC(50) of 13 microM inhibited over 70% of plasmalemmal NCX activity (P<0.01) but not NCKX activity. Our data suggest that the effects of CGP-37157 on neuronal Ca(2+) homeostasis include inhibition of certain plasmalemmal NCX isoform(s). Because cerebellar granule cells robustly express NCX3 transcripts, which are not expressed in the heart, it appears that this isoform may be CGP-37157 sensitive.

In depolarized and glucose-deprived neurons, Na+ influx reverses plasmalemmal K+-dependent and K+-independent Na+/Ca2+ exchangers and contributes to NMDA excitotoxicity

Cerebellar granule cells (CGCs) express K+-dependent (NCKX) and K+-independent (NCX) plasmalemmal Na+/Ca2+ exchangers which, under plasma membrane-depolarizing conditions and high cytosolic [Na+], may reverse and mediate potentially toxic Ca2+ influx. To examine this possibility, we inhibited NCX or NCKX with KB-R7943 or K+-free medium, respectively, and studied how gramicidin affects cytosolic [Ca2+] and 45Ca2+ accumulation. Gramicidin forms pores permeable to alkali cations but not Ca2+. Therefore, gramicidin-induced Ca2+ influx is indirect; it results from fluxes of monovalent cations. In the presence of Na+, but not Li+ or Cs+, gramicidin induced Ca2+ influx that was inhibited by simultaneous application of KB-R7943 and K+-free medium. The data indicate that gramicidin-induced Na+ influx reverses NCX and NCKX. To test the role of NCX and/or NCKX in excitotoxicity, we studied how NMDA affects the viability of glucose-deprived and depolarized CGCs. To assure depolarization of the plasma membrane, we inhibited Na+,K+-ATPase with ouabain. Although inhibition of NCX or NCKX reversal failed to significantly limit 45Ca2+ accumulation and excitotoxicity, simultaneously inhibiting NCX and NCKX reversal was neuroprotective and significantly decreased NMDA-induced 45Ca2+ accumulation. Our data suggest that NMDA-induced Na+ influx reverses NCX and NCKX and leads to the death of depolarized and glucose-deprived neurons.

Preferential expression of plasmalemmal K-dependent Na+/Ca2+ exchangers in neurons versus astrocytes

Numerous isoforms of plasmalemmal K-dependent (NCKX) and K-independent (NCX) Na+/Ca2+ exchangers are expressed in the brain. The physiological functions of each isoform are presently unknown. Therefore, in this study, we compared expression of NCKX and NCX transcripts between primary cultures of cerebellar granule cells, and astrocytes. Northern blot analysis showed that granule cells expressed NCKX2, NCKX3, NCKX4 and NCX3, whereas astrocytes expressed primarily NCX1. Consistent with this molecular characterization, a significant fraction of 45Ca2+ accumulation in Na-loaded granule cells, but not in astrocytes, depended on external K+. This is the first demonstration of native NCKX activity in neurons derived from the central nervous system. Our data suggest that NCKX isoform expression may correspond to the unique Ca2+ homeostasis requirements of neurons.

Instrumental role of Na+ in NMDA excitotoxicity in glucose-deprived and depolarized cerebellar granule cells

In glucose-deprived cerebellar granule cells, substitution of extracellular Na+ with Li+ or Cs+ prevented N-methyl-D-aspartate (NMDA)-induced excitotoxicity. NMDA stimulated 45Ca2+ accumulation and ATP depletion in a Na-dependent manner, and caused neuronal death, even if applied while Na,K-ATPase was inhibited by 1 mM ouabain. The cells treated with NMDA in the presence of ouabain accumulated sizable 45Ca2+ load but most of them failed to elevate cytosolic [Ca2+] upon mitochondrial depolarization. Na/Ca exchange inhibitor, KB-R7943, inhibited Na-dependent and NMDA-induced 45Ca2+ accumulation but only if Na,K-ATPase activity was compromised by ouabain. In cells energized by glucose and exposed to NMDA without ouabain, KB-R7943 reduced NMDA-elicited ionic currents by 19% but failed to inhibit 45Ca2+ accumulation. It appears that a large part of NMDA-induced Ca2+ influx in depolarized and glucose-deprived cells is mediated by reverse Na/Ca exchange. A high level of reverse Na/Ca exchange operation is maintained by a sustained Na+ influx via NMDA channels and depolarization of the plasma membrane. In cells energized by glucose, however, most Ca2+ enters directly via NMDA channels because Na,K-ATPase regenerating Na+ and K+ concentration gradients prevents Na/Ca exchange reversal. Since under these conditions Na/Ca exchange extrudes Ca2+, its inhibition destabilizes Ca2+ homeostasis.

Repolarization of the plasma membrane shapes NMDA-induced cytosolic [Ca2+ ] transients

After inactivation of NMDA receptors, restoration of basal cytosolic [Ca2+] ([Ca2+]c) is delayed. This may be caused by Ca2+ influx via reverse Na/Ca exchange or voltage-gated Ca2+ channels, and/or by Ca2+ efflux from internal stores. Monitoring of [Na+]c, [Ca2+]c, and plasma membrane potential in cultured cerebellar granule cells showed that repolarization of the plasma membrane and inactivation of voltage-gated Ca channels plays the most critical role in restoration of low [Ca2+]c following NMDA receptor inactivation. During NMDA receptor activation, however, an Na-dependent mechanism enhanced NMDA-induced elevation in [Ca2+]c. This mechanism did not involve Na,K-ATPase activation by Na+, because it operated even when Na,K-ATPase was inhibited.

Kainate-induced K+ efflux and plasma membrane depolarization in cultured cerebellar granule cells

It is becoming increasingly evident that activation of ionotropic glutamate receptors leads to significant changes in cytosolic [K+] ([K+]c), a major determinant of the plasma membrane (PM) potential, Em. Since Em affects fluxes of key cations, such as Ca2+, it is important to precisely quantify [K+]c and Em in neurons exposed to glutamate receptor agonists. Here we studied the relationships between [K+]c and Em in primary cultures of cerebellar granule cells, and found that kainate elicits a rapid drop in [K+]c below 10 mM. Using patch electrodes containing 10 or 150 mM K+, we determined that kainate depolarizes the PM to -2 or -28 mV, respectively. Therefore, the actual PM depolarization elicited by kainate is much larger than that routinely measured with K+-rich electrodes.

Elevated extracellular K(+) concentrations inhibit N-methyl-D-aspartate-induced Ca(2+) influx and excitotoxicity

Although extracellular [K(+)] ([K(+)](E)) is highly elevated during brain ischemia, in vitro studies aimed at explaining the mechanisms of excitotoxicity have been conducted at low [K(+)](E). Whether high [K(+)](E) affects excitotoxicity has not been formally addressed. Therefore this study, using digital fluorescence microscopy, tested how the elevation of [K(+)](E) from 5.6 to 60 mM affects N-methyl-D-aspartate (NMDA)-induced Ca(2+) and Na(+) influx, plasma membrane (PM) potential, mitochondrial Ca(2+) load, and viability of primary cultures of rat cerebellar granule cells. High [K(+)](E) curtailed the NMDA-induced Ca(2+) and Na(+) influx and mitochondrial Ca(2+) overload, and prevented neuronal death. Surprisingly, the inhibitory effect of high [K(+)](E) on the NMDA-induced Ca(2+) influx could not be linked to depolarization of the PM. Apparently, the PM of cerebellar granule cells exposed to NMDA was more depolarized at low than at high [K(+)](E), probably because the NMDA-induced Na(+) influx was greatly enhanced when the extracellular [Na(+)]/[K(+)] ratio was increased. When this ratio was small, i.e., at high [K(+)](E), the NMDA-induced increase in cytoplasmic [Na(+)] was suppressed, preventing Ca(2+) influx via the reverse operation of the Na(+)/Ca(2+) exchanger, which may explain the inhibitory effect of high [K(+)](E) on NMDA-induced Ca(2+) influx and excitotoxicity.

N-methyl-D-aspartate excitotoxicity: relationships among plasma membrane potential, Na(+)/Ca(2+) exchange, mitochondrial Ca(2+) overload, and cytoplasmic concentrations of Ca(2+), H(+), and K(+)

A high cytoplasmic Na(+) concentration may contribute to N-methyl-D-aspartate (NMDA)-induced excitotoxicity by promoting Ca(2+) influx via reverse operation of the Na(+)/Ca(2+) exchanger (NaCaX), but may simultaneously decrease the electrochemical Ca(2+) driving force by depolarizing the plasma membrane (PM). Digital fluorescence microscopy was used to compare the effects of Na(+) versus ions that do not support the NaCaX operation, i.e., N-methyl-D-glucamine(+) or Li(+), on: PM potential; cytoplasmic concentrations of Ca(2+), H(+), and K(+); mitochondrial Ca(2+) storage; and viability of primary cultures of cerebellar granule cells exposed to NMDA receptor agonists. In the presence of Na(+) or Li(+), NMDA depolarized the PM and decreased cytoplasmic pH (pH(C)); in the presence of Li(+), Ca(2+) influx was reduced, mitochondrial Ca(2+) overload did not occur, and the cytoplasm became more acidified than in the presence of Na(+). In the presence of N-methyl-D-glucamine(+), NMDA instantly hyperpolarized the PM, but further changes in PM potential and pH(C) were Ca-dependent. In the absence of Ca(2+), hyperpolarization persisted, pH(C) was decreasing very slowly, K(+) was retained in the cytoplasm, and cerebellar granule cells survived the challenge; in the presence of Ca(2+), pH(C) dropped rapidly, the K(+) concentration gradient across the PM began to collapse as the PM began to depolarize, and Ca(2+) influx and excitotoxicity greatly increased. These results indicate that the dominant, very likely excitotoxic, component of NMDA-induced Ca(2+) influx is mediated by reverse NaCaX and that direct Ca(2+) influx via NMDA channels is curtailed by Na-dependent PM depolarization.

The difference between mechanisms of kainate and glutamate excitotoxicity in vitro: osmotic lesion versus mitochondrial depolarization

The hypothesis that a destabilization of mitochondrial function during neuronal exposure to excitatory amino acids may be involved in the mechanism of neuronal death was examined. The mitochondrial membrane potential (Delta(psi)m) and the cytoplasmic Ca2+ concentration ([Ca2+]c) were monitored simultaneously in single cultured rat cerebellar granule cells (CGCs) loaded with tetramethylrhodamine methyl ester (TMR) and fura-2; CGCs were depolarized with K+, or exposed to excitotoxic doses of glutamate or kainate, and viability of the same neurons was studied for 24-30 h. This approach made it possible to single out the neurons that died, and to describe the changes in Delta(psi)m and [Ca2+]c that were characteristic for these neurons. Exposure to glutamate caused an increase in [Ca2+]c that was associated with a decrease in the mitochondrial TMR fluorescence, which indicates a decrease in Delta(psi)m. The neurons that failed to restore Delta(psi)m following glutamate withdrawal, also failed to restore low [Ca2+]c, and later died. Although a similar number of neurons died following kainate exposure as did after glutamate exposure, the kainate-elicited neuronal death resulted not from the collapse of Delta(psi)m but from an excessive neuronal swelling, which led to rupture of the plasma membrane. Depolarization with K+ was not neurotoxic and caused only a minor decrease in TMR fluorescence. These results indicate that in vitro glutamate and kainate destroy neurons by different mechanisms: glutamate by a failure to restore Delta(psi)m following the exposure, and kainate by an osmotic lesion of the plasma membrane.

Glutamate-induced destabilization of intracellular calcium concentration homeostasis in cultured cerebellar granule cells: role of mitochondria in calcium buffering

The exposure of cultured cerebellar granule cells for 4 min to glutamate (50 microM) in a Mg2+-free medium containing 10 microM glycine elicited a prompt increase of the intracellular Ca2+ concentration ([Ca2+]i) to 5 microM, which was followed by a decline to 1.5 microM (as measured using fura-2); both events occurred while the glutamate pulse increased the intracellular sodium concentration ([Na+]i) to an estimated 60-100 mM. Because under these circumstances the plasma membrane Na+/Ca2+ exchanger cannot extrude Ca2+, other mechanisms should operate in causing the [Ca2+]i decline. To evaluate a possible role of intracellular Ca2+ stores in Ca2+ buffering, thapsigargin, ryanodine, and dantrolene were tested. Thapsigargin (1 microM) and ryanodine (10 microM) failed to modify the glutamate-elicited [Ca2+]i transients; results with dantrolene could not be considered because this drug by itself affected the fura-2 fluorescence. In contrast, carbonyl cyanide m-chlorophenylhydrazone (1 microM) and antimycin A1 (1 microM), which dissipate mitochondrial membrane potential by different mechanisms, virtually abolished the [Ca2+]i decline occurring either during glutamate application or after its removal. Moreover, when the residual [Na+]i increase persisting after glutamate removal was artificially abated, the Ca2+-buffering capacity of neurons was significantly improved. These data suggest that most of the Ca2+ entering the neurons during excitotoxic glutamate exposure is diverted to mitochondria and that the glutamate-induced increase of [Na+]i limits this mitochondrial Ca2+-buffering capacity, presumably via activation of the mitochondrial Na+/Ca2+ exchanger.

Intracellular sodium concentration in cultured cerebellar granule cells challenged with glutamate

We monitored simultaneously the changes in the intracellular sodium concentration ([Na+]i) and intracellular calcium concentration ([Ca2+]i) in individual neurons from primary cultures of cerebellar granule cells loaded with sodium-binding benzofuran isophthalate and fluo-3. An application of glutamate (50 microM) in Mg(2+)-free medium containing 10 microM glycine evoked [Na+]i and [Ca2+]i increases that exceeded 60 mM and 1 microM, respectively. The kinetics of [Na+]i and [Ca2+]i decreases after the termination of the glutamate pulse were different. [Na+]i failed to decrease immediately after glutamate withdrawal and the delay in the onset of [Na+]i decrease after the glutamate pulse termination was proportional to the glutamate dose, the glutamate pulse duration, and the extent of [Ca2+]i elevation elicited by glutamate. The kinetics of [Ca2+]i decrease were biphasic, with the first phase occurring immediately after glutamate withdrawal and the second phase being correlated in time with a [Na+]i value lower than 15-20 mM. These results were interpreted to indicate that the glutamate-evoked calcium influx may lead to sodium homeostasis destabilization. The delay in the restoration of the sodium gradient may in turn prolong the neuronal exposure to toxic [Ca2+]i values, due to the decrease in the efficiency of the Na+/Ca2+ exchanger to extrude calcium. The glutamate effects on [Na+]i and [Ca2+]i were potentiated by glycine. Glycine (10 microM) added alone also evoked [Na+]i and [Ca2+]i increases; this effect was inhibited by a competitive inhibitor of the N-methyl-D-aspartate receptor, 3-(2-carboxypiperazin-4-yl)propyl-1-phosphonic acid, indicating an involvement of endogenous glutamate.

Glutamate impairs neuronal calcium extrusion while reducing sodium gradient

The rate of decrease of neuronal [Ca2+]i after an elevation induced by a glutamate pulse is much slower than that after a comparable [Ca2+]i elevation induced by a K+ depolarization. To investigate whether the [Na+]i increase taking place during the glutamate pulse reduces the rate of Ca2+ extrusion, we monitored simultaneously [Na+]i and [Ca2+]i during a K+ depolarization and a glutamate pulse lasting 1 min. The K+ depolarization evoked only a transient increase of [Na+]i from 4 mM to 13 mM, whereas the glutamate pulse increased [Na+]i to 60 mM, and this increase persisted after glutamate removal. An application of bepridil immediately after glutamate pulse when [Na+]i was greatly elevated, but not 14 min after glutamate removal when a basal [Na+]i was restored, evoked a [Ca2+]i increase accompanied by a decrease of [Na+]i, indicating a reverse mode of operation of the Na+/Ca2+ exchanger. These data suggest that the glutamate-evoked increase in [Na+]i may play a role in Ca2+ homeostasis destabilization.

In vitro interaction between cerebellar astrocytes and granule cells: a putative role for nitric oxide

In primary cultures of astrocytes and granule cells from neonatal rat cerebellum, the activity and function of nitric oxide (NO) synthase were measured by the conversion of [3H]arginine to [3H]citrulline and the accumulation of cyclic guanosine monophosphate (cGMP), respectively. The glutamate receptor agonist N-methyl-D-aspartate (NMDA) and the Ca2+ ionophore A23187 stimulated NO synthase activity in cerebellar granule cells but not in astrocytes. In granule cells, NMDA, A23187, and sodium nitroprusside (SNP) elicited an accumulation of cGMP, whereas only SNP was active in astrocytes. However, in astrocytes that were incubated together with granule cells, NMDA induced a more than 3-fold increase in the concentration of cGMP; this increase was blocked by both the NO synthase inhibitor NG-monomethyl-L-arginine (MeArg) and the allosteric NMDA receptor antagonist (+)5-methyl-10,11-dihydro-5H-dibenzocyclohepten-5,10-imine maleate (MK-801). Thus, cerebellar astrocytes do not appear to express NO synthase but do contain guanylate cyclase, which can be activated by an NO-like factor produced by cerebellar granule cells after stimulation by NMDA.

Sodium nitroprusside inhibits N-methyl-D-aspartate-evoked calcium influx via a nitric oxide- and cGMP-independent mechanism

In primary cultures of rat cerebellar granule cells, sodium nitroprusside (SNP), a vasodilator that generates nitric oxide (NO), potently inhibited N-methyl-D-aspartate (NMDA)-evoked 45Ca2+ influx (IC50 = 6.6 microM). This inhibition was time dependent and was complete when SNP was applied 10 min before NMDA stimulation. The effect of SNP was transient and the ability of NMDA to stimulate 45Ca2+ influx was restored after SNP withdrawal. The effect of SNP was selective for the NMDA-sensitive glutamate receptor, because SNP failed to antagonize kainate-stimulated 45Ca2+ influx. The action of SNP was independent of the ability of this agent to generate NO; S-nitroso-N-acetylpenicillamine, an NO-containing compound that was 100 times more potent than SNP in stimulating cGMP accumulation, failed to inhibit NMDA-evoked 45Ca2+ influx. In contrast, K4Fe(CN)6, a compound structurally similar to SNP but devoid of NO, inhibited both 45Ca2+ influx (IC50 = 27 microM) and cGMP accumulation evoked by NMDA; K3Fe(CN)6 was inactive. Thus, in cerebellar granule cells, SNP and K4Fe(CN)6 interfere with the function of NMDA receptors, possibly at the level of the receptor recognition site. The resulting blockade of Ca2+ influx through NMDA receptor channels accounts for the reported ability of these compounds to protect granule cells from NMDA-induced neurotoxicity. This protection is not mediated by an NO-dependent mechanism but depends on the action of the ferrocyanide portion of the SNP molecule.

Glutamate receptor agonists stimulate nitric oxide synthase in primary cultures of cerebellar granule cells

The glutamate receptor agonist N-methyl-D-aspartate (NMDA) stimulated a rapid, extracellular Ca(2+)-dependent conversion of [3H]arginine to [3H]citrulline in primary cultures of cerebellar granule cells, indicating receptor-mediated activation of nitric oxide (NO) synthase. The NMDA-induced formation of [3H]citrulline reached a plateau within 10 min. Subsequent addition of unlabeled L-arginine resulted in the disappearance of 3H from the citrulline pool, indicating a persistent activation of NO synthase after NMDA receptor stimulation. Glutamate, NMDA, and kainate, but not quisqualate, stimulated both the conversion of [3H]arginine to [3H]citrulline and cyclic GMP accumulation in a dose-dependent manner. Glutamate and NMDA showed similar potencies for the stimulation of [3H]citrulline formation and cyclic GMP synthesis, respectively, whereas kainate was more potent at inducing cyclic GMP accumulation than at stimulating [3H]citrulline formation. Both the [3H]arginine to [3H]citrulline conversion and cyclic GMP synthesis stimulated by NMDA were inhibited by the NMDA receptor antagonist MK-801 and by the inhibitors of NO synthase, NG-monomethyl-L-arginine (MeArg) and NG-nitro-L-arginine (NOArg). However, MeArg, in contrast to NOArg, also potently inhibited [3H]arginine uptake. Kainate (300 microM) stimulated 45Ca2+ influx to the same extent as 100 microM NMDA, but stimulated [3H]citrulline formation to a much lesser extent, which suggests that NO synthase is localized in subcellular compartments where the Ca2+ concentration is regulated mainly by the NMDA receptor.

Inhibition of glutamate-induced cell death by sodium nitroprusside is not mediated by nitric oxide

Pretreatment of primary cultures of cerebellar granule cells with sodium nitroprusside (SNP) protected these neurons from delayed death induced by glutamate and N-methyl-D-aspartate (NMDA). This neuroprotective effect was not mimicked by S-nitroso-N-acetylpenicillamine (SNAP) which like SNP stimulates guanylate cyclase via a nitric oxide (NO) related mechanism. In contrast, neuroprotection was achieved with potassium ferrocyanide, a compound structurally related to SNP, but devoid of NO. On the other hand, kainate-induced neurotoxicity was not protected but potentiated by SNP. This effect of SNP was not mimicked by SNAP, potassium ferrocyanide and potassium ferricyanide. We conclude that neuroprotective properties of SNP on glutamate- and NMDA-induced neurotoxicity are not due to the release of NO and activation of guanylate cyclase, but are determined by the ferrocyanide portion of the SNP molecule.

The distribution of serotonergic 5-HT1A and non-5-HT1A recognition sites along the dorso-ventral axis of the rat hippocampus

The distribution of serotonergic 5-HT1 binding sites along the hippocampal dorso-ventral axis was compared with [3H]5-HT uptake considered as a marker of the quantity of serotonergic nerve terminals. [3H]5-HT binding to 5-HT1A and non-5-HT1A sites, of high and low affinity for spiperone, respectively, was investigated in three parts of the hippocampus: dorsal, medial and ventral. In each hippocampal part, 5-HT1A sites constituted approximately 70% of binding sites. [3H]5-HT uptake and [3H]5-HT binding to 5-HT1A and non-5-HT1A sites were significantly higher in the ventral than in the dorsal part of the hippocampus. The dorso-ventral hippocampal gradient in [3H]5-HT binding to both 5-HT1A and non-5-HT1A sites was due to an increase of the density (Bmax) of these sites along the longitudinal hippocampal axis, but not their affinity (Kd) for [3H]5-HT. The results are discussed in the context of the previously described mismatch between the localization of serotonergic nerve terminals and serotonergic receptors in the hippocampus.

The effect of GM1 ganglioside on cholinergic and serotoninergic systems in the rat hippocampus following partial denervation is dependent on the degree of fiber degeneration

The partial lesion paradigm of the dorsal hippocampal afferents in the rat was used as a model to study the effect of GM1 ganglioside treatment on recovery of neurotransmitter markers of the cholinergic and serotoninergic activity in various hippocampal regions. It was found that the enhancement of recovery of acetylcholinesterase, choline acetyltransferase and serotonin uptake by GM1 treatment (30 mg/kg i.m., daily), as studied on the 6th and 21st postlesion day, was dependent on the degree of fiber degeneration. The results may be interpreted in terms of the relationship between the action of GM1 and that of neuronotrophic factors whose release also depends on the extent of the fiber degeneration. These data indicate that GM1 elicits the recovery of biochemical parameters, or fails to, depending on the specificity of the trauma. The result may explain why, after certain brain lesions, GM1 does not promote functional recovery.

Disappearance of low affinity adenosine binding sites in aging rat cerebral cortex and hippocampus

A1 adenosine receptor binding was investigated, using the selective agonist, [3H]cyclohexyladenosine, on membranes prepared from the cerebral cortex and hippocampus of 3- and 24-month-old rats. The Scatchard analysis of the binding results obtained in the cerebral cortex of young animals showed two distinct binding sites with apparent Kd of 2 and 24 nM and Bmax of 259 and 675 fmol/mg protein, respectively. Conversely, in the old rats only one population of high affinity binding sites with a Kd of 2.2 nM and a Bmax of 450 fmol/mg protein was found. Displacement curves of labelled ligand carried out on hippocampal membranes also demonstrate the disappearance of a low affinity subpopulation of A1 receptors in the old rat brain.