Neurons containing NADPH-diaphorase are selectively resistant to quinolinate toxicity.

Exposure of cultures of cortical cells from mouse to either of the endogenous excitatory neurotoxins quinolinate or glutamate resulted in widespread neuronal destruction; but only in the cultures exposed to quinolinate, an N-methyl-D-aspartate agonist, was there a striking preservation of the subpopulation of neurons containing the enzyme nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-d). Further investigation revealed that neurons containing NADPH-d were also resistant to the toxicity of N-methyl-D-aspartate itself but were selectively vulnerable to the toxicity of either kainate or quisqualate. Thus, neurons containing NADPH-d may have an unusual distribution of receptors for excitatory amino acids, with a relative lack of N-methyl-D-aspartate receptors and a relative preponderance of kainate or quisqualate receptors. Since selective sparing of neurons containing NADPH-d is a hallmark of Huntington's disease, the results support the hypothesis that the disease may be caused by excess exposure to quinolinate or some other endogenous N-methyl-D-aspartate agonist.

Potentiated necrosis of cultured cortical neurons by neurotrophins.

The effects of neurotrophins on several forms of neuronal degeneration in murine cortical cell cultures were examined. Consistent with other studies, brain-derived neurotrophic factor, neurotrophin-3, and neurotrophin-4/5 all attenuated the apoptotic death induced by serum deprivation or exposure to the calcium channel antagonist nimodipine. Unexpectedly, however, 24-hour pretreatment with these same neurotrophins markedly potentiated the necrotic death induced by exposure to oxygen-glucose deprivation or N-methyl-D-aspartate. Thus, certain neurotrophins may have opposing effects on different types of death in the same neurons.

Nonproteolytic neuroprotection by human recombinant tissue plasminogen activator.

Human recombinant tissue plasminogen activator (tPA) may benefit ischemic stroke patients by dissolving clots. However, independent of thrombolysis, tPA may also have deleterious effects on neurons by promoting excitotoxicity. Zinc neurotoxicity has been shown to be an additional key mechanism in brain injuries. Hence, if tPA affects zinc neurotoxicity, this may provide additional insights into its effect on neuronal death. Independent of its proteolytic action, tPA markedly attenuated zinc-induced cell death in cortical culture, and, when injected into cerebrospinal fluid, also reduced kainate seizure-induced hippocampal neuronal death in adult rats.

The role of zinc in selective neuronal death after transient global cerebral ischemia.

Zinc is present in presynaptic nerve terminals throughout the mammalian central nervous system and likely serves as an endogenous signaling substance. However, excessive exposure to extracellular zinc can damage central neurons. After transient forebrain ischemia in rats, chelatable zinc accumulated specifically in degenerating neurons in the hippocampal hilus and CA1, as well as in the cerebral cortex, thalamus, striatum, and amygdala. This accumulation preceded neurodegeneration, which could be prevented by the intraventricular injection of a zinc chelating agent. The toxic influx of zinc may be a key mechanism underlying selective neuronal death after transient global ischemic insults.

Age and body weight adjusted warfarin initiation program for ischaemic stroke patients.

BACKGROUND: Despite its proven effect, anticoagulation is not recommended to the acute ischaemic stroke due to the risk of bleeding complications. The purpose of this study is development of individualized warfarin initiation program for acute or subacute stroke patients. METHODS: Among stroke patients who regularly visited out-patient clinics, we included patients who have continuously taken the same dose of warfarin as the prothrombin time remained at target International Nomarlized Ratio (INR). We assessed potential variables that affect the maintenance dose of warfarin. Using these variables, we developed an individualized warfarin initiation program. RESULTS: The median warfarin maintenance dose (interquartile range) in the 321 included patients was 4 (3-5) mg per day. Age (adjusted R(2) = 0.221, P < 0.001) and body weight (added to age, adjusted R(2) = 0.238, P = 0.008) were significant predicting factors of the dose. We classified the maintenance doses into high (HG), standard, and low group (LG) based on the distribution of maintenance doses. Decision tree analysis categorized younger (or=55 kg) patients into HG, and very old (>or=80 years old) or low body weight (<55 kg among those >56 years old) patients into LG. We recommend 7 mg of warfarin as a standard initial dose, but 10 mg was recommended for HG patients and 5 mg for LG. CONCLUSION: We expect that this individualized program may reduce the time to target INR without excessive anticoagulation. Further prospective studies are needed to reveal the efficacy and safety of applying this program for acute stroke patients.

AMPA receptor activation potentiates zinc neurotoxicity.

Extracellular Zn2+ attenuates NMDA receptor-mediated neurotoxicity and increases AMPA receptor-mediated toxicity. Known electrophysiological effects of Zn2+ predict only the former. We considered the possibility that the latter rather reflects AMPA potentiation of Zn2+ toxicity, perhaps mediated by neuronal depolarization and Zn2+ entry through voltage-gated Ca2+ channels. High K+ or kainate also potentiated Zn2+ toxicity, and AMPA plus Zn2+ toxicity was attenuated by raising extracellular Ca2+, or by Ca2+ channel blockers. AMPA plus Zn2+ exposure induced an increase in fluorescence from neurons loaded with the Zn(2+)-sensitive dye TS-Q and increased subsequent 45Ca2+ accumulation. The ability of AMPA receptor activation to potentiate Zn2+ toxicity may be relevant to neuronal death associated with intense activation of glutamatergic pathways.

Involvement of the BLT2 receptor in the itch-associated scratching induced by 12-(S)-lipoxygenase products in ICR mice.

BACKGROUND AND PURPOSE: Recently, we reported that 12(S)-HPETE (12(S)-hydroperoxyeicosa-5Z,8Z,10E,14Z-tetraenoic acid) induces scratching in ICR mice. We hypothesized that 12(S)-HPETE might act as an agonist of the low-affinity leukotriene B4 receptor BLT2. To confirm the involvement of the BLT2 receptor in 12(S)-HPETE-induced scratching, we studied the scratch response using the BLT2 receptor agonists compound A (4'-[[pentanoyl (phenyl) amino]methyl]-1,1'-biphenyl-2-carboxylic acid) and 12(S)-HETE (12(S)-hydroxyeicosa-5Z,8Z,10E,14Z-tetraenoic acid). EXPERIMENTAL APPROACH: A video recording was used to determine whether the BLT2 receptor agonists caused itch-associated scratching in ICR mice. Selective antagonists and several chemicals were used. KEY RESULTS: Both 12(S)-HETE and compound A dose dependently induced scratching in the ICR mice. The dose-response curve for compound A showed peaks at around 0.005-0.015 nmol per site. Compound A- and 12(S)-HETE-induced scratching was suppressed by capsaicin and naltrexon. We examined the suppressive effects of U75302 (6-[6-(3-hydroxy-1E,5Z-undecadienyl)-2-pyridinyl]-1,5-hexanediol, the BLT1 receptor antagonist) and LY255283 (1-[5-ethyl-2-hydroxy-4-[[6-methyl-6-(1H-tetrazol-5-yl)heptyl]oxy]phenyl]-ethanone, the BLT2 receptor antagonist) on the BLT2 agonist-induced scratching. LY255283 suppressed compound A- and 12(S)-HETE-induced scratching, but U75302 did not. LY255283 required a higher dose to suppress the compound A-induced scratching than it did to suppress the 12(S)-HETE-induced scratching. One of the BLT(2) receptor agonists, 12(R)-HETE (12(R)-hydroxyeicosa-5Z,8Z,10E,14Z-tetraenoic acid), also induced scratching in the ICR mice. CONCLUSIONS AND IMPLICATIONS: Our present results corroborate the hypothesis that the BLT2 receptor is involved in 12(S)-lipoxygenase-product-induced scratching in ICR mice. We also confirmed that this animal model could be a valuable means of evaluating the effects of BLT2 receptor antagonists.

Overproduction of PDR3 suppresses mitochondrial import defects associated with a TOM70 null mutation by increasing the expression of TOM72 in Saccharomyces cerevisiae.

Most mitochondrial proteins are synthesized with cleavable amino-terminal targeting signals that interact with the mitochondrial import machinery to facilitate their import from the cytosol. We previously reported that the presequence of the F(1)-ATPase beta subunit precursor (pre-F(1)beta) acts as an intramolecular chaperone that maintains the precursor in an import-competent conformation prior to import (P. Hajek, J. Y. Koh, L. Jones, and D. M. Bedwell, Mol. Cell. Biol. 17:7169-7177, 1997). We also found that a mutant form of pre-F(1)beta with a minimal targeting signal (Delta 1,2 pre-F(1)beta) is inefficiently imported into mitochondria because it rapidly folds into an import-incompetent conformation. We have now analyzed the consequences of reducing the pre-F(1)beta targeting signal to a minimal unit in more detail. We found that Delta 1,2 pre-F(1)beta is more dependent upon the Tom70p receptor for import than WT pre-F(1)beta is, resulting in a growth defect on a nonfermentable carbon source at 15 degrees C. Experiments using an in vitro mitochondrial protein import system suggest that Tom70p functions to maintain a precursor containing the Delta 1,2 pre-F(1)beta import signal in an import-competent conformation. We also identified PDR3, a transcriptional regulator of the pleiotropic drug resistance network, as a multicopy suppressor of the mitochondrial import defects associated with Delta 1,2 pre-F(1)beta in a tom70 Delta strain. The overproduction of PDR3 mediated this effect by increasing the import of Delta 1,2 pre-F(1)beta into mitochondria. This increased the mitochondrial ATP synthase activity to the extent that growth of the mutant strain was restored under the selective conditions. Analysis of the transcription patterns of components of the mitochondrial outer membrane import machinery demonstrated that PDR3 overproduction increased the expression of TOM72, a little studied TOM70 homologue. These results suggest that Tom72p possesses overlapping functions with Tom70p and that the pleiotropic drug resistance network plays a previously unappreciated role in mitochondrial biogenesis.

The amino terminus of the F1-ATPase beta-subunit precursor functions as an intramolecular chaperone to facilitate mitochondrial protein import.

Mitochondrial import signals have been shown to function in many steps of mitochondrial protein import. Previous studies have shown that the F1-ATPase beta-subunit precursor (pre-F1beta) of the yeast Saccharomyces cerevisiae contains an extended, functionally redundant mitochondrial import signal at its amino terminus. However, the full significance of this functionally redundant targeting sequence has not been determined. We now report that the extended pre-F1beta signal acts to maintain the precursor in an import-competent conformation prior to import, in addition to its previously characterized roles in mitochondrial targeting and translocation. We found that this extended signal is required for the efficient posttranslational mitochondrial import of pre-F1beta both in vivo and in vitro. To determine whether the pre-F1beta signal directly influences precursor conformation, fusion proteins that contain wild-type and mutant forms of the pre-F1beta import signal attached to the model passenger protein dihydrofolate reductase (DHFR) were constructed. Deletions that reduced the import signal to a minimal functional unit decreased both the half-time of precursor folding and the efficiency of mitochondrial import. To confirm that the reduced mitochondrial import associated with this truncated signal was due to a defect in its ability to maintain DHFR in a loosely folded conformation, we introduced structurally destabilizing missense mutations into the DHFR passenger to block precursor folding independently of the import signal. We found that the truncated signal imported this destabilized form of DHFR as efficiently as the intact targeting signal, indicating that the primary defect associated with the minimal signal is an inability to maintain the precursor in a loosely folded conformation. Our results suggest that the loss of this intramolecular chaperone function leads to defects in the early stages of the import process.

Induction and activation by zinc of NADPH oxidase in cultured cortical neurons and astrocytes.

Zinc overload may be a key mechanism of neuronal death in acute brain injury. We have demonstrated previously that zinc overload neurotoxicity involves protein kinase C (PKC)-dependent rises in intracellular levels of reactive oxygen species (ROS). However, the cascade linking PKC activation to ROS generation in cultured cortical neurons has been unknown. A recent study has demonstrated that ROS-generating NADPH oxidase is present in sympathetic neurons and contributes to NGF deprivation-induced cell death. Because NADPH oxidase is activated by PKC, in the present study, we examined the possibility that NADPH oxidase is the effector for oxidative stress in zinc-overloaded cortical cells. Reverse transcription-PCR and Western blot analyses revealed that naive cultured cortical cells express subunits of NADPH oxidase at low levels. Exposure to zinc substantially increased levels of NADPH oxidase subunits in both neurons and astrocytes. In addition, zinc exposure induced translocation of the p47(PHOX) and p67(PHOX) subunits to the membrane, a signature event for NADPH oxidase activation. Addition of a selective PKC inhibitor, GF109203X, blocked both the induction and the membrane translocation of NADPH oxidase by zinc. Supporting the role for NADPH oxidase in zinc-triggered oxidative injury, NADPH oxidase inhibitors attenuated ROS production and cortical neuronal death induced by zinc. In addition, Cu/Zn-superoxide dismutase and catalase attenuated zinc-induced cortical neuronal death. Our results have demonstrated that zinc overload induces and activates NADPH oxidase in cortical neurons and astrocytes in a PKC-dependent manner. Thus, NADPH oxidase may be an enzyme contributing to ROS generation in zinc-overloaded cortical neurons and astrocytes.

Co-induction of p75NTR and p75NTR-associated death executor in neurons after zinc exposure in cortical culture or transient ischemia in the rat.

Recently, a 22 kDa protein termed p75(NTR)-associated death executor (NADE) was discovered to be a necessary factor for p75(NTR)-mediated apoptosis in certain cells. However, the possible role for p75(NTR)/NADE in pathological neuronal death has yet been undetermined. In the present study, we have examined this possibility in vivo and in vitro. Exposure of cortical cultures to zinc induced both p75(NTR) and NADE in neurons, whereas exposure to NMDA, ionomycin, iron, or H(2)O(2) induced neither. In addition, zinc exposure increased neuronal NGF expression and its release into the medium. A function-blocking antibody of p75(NTR) (REX) inhibited association between p75(NTR) and NADE as well as neuronal death induced by zinc. Conversely, NGF augmented zinc-induced neuronal death. Caspase inhibitors reduced zinc-induced neuronal death, indicating that caspases were involved. Because reduction of NADE expression with cycloheximide or NADE antisense oligonucleotides attenuated zinc-induced neuronal death, NADE appears to contribute to p75(NTR)-induced cortical neuronal death as shown in other cells. Because zinc neurotoxicity may be a key mechanism of neuronal death after transient forebrain ischemia, we next examined this model. After ischemia, p75(NTR) and NADE were induced in degenerating rat hippocampal CA1 neurons. There was a close correlation between zinc accumulation and p75(NTR)/NADE induction. Suggesting the role of zinc here, injection of a metal chelator, CaEDTA, into the lateral ventricle completely blocked the induction of p75(NTR) and NADE. Our results suggest that co-induction of p75(NTR) and NADE plays a role in zinc-triggered neuronal death in vitro and in vivo.

Histochemically reactive zinc in plaques of the Swedish mutant beta-amyloid precursor protein transgenic mice.

Endogenous metals such as zinc may contribute to beta-amyloid (Abeta) aggregation and hence the plaque formation. In the present study, we examined brains of four Swedish mutant amyloid precursor protein (APP) transgenic mice at 12 months of age for histochemically reactive zinc in the plaques. Here, we report that all the Congo red (+) mature plaques contained chelatable zinc, as demonstrated by staining with the zinc-specific fluorescent dye 6-methoxy-8-quinolyl-para-toluenesulfonamide (TSQ). On the other hand, Congo red (-) preamyloid Abeta deposits were not stained with TSQ. Interestingly, although cerebellum contained similar degree of preamyloid Abeta deposits as cerebral cortex, it was completely devoid of Congo red- or TSQ-stained mature plaques. Although zinc from plaques was only slowly and partially removed by a specific zinc remover, dithizone, treatment of brain sections with heparinase-III, which degrades heparan sulfate proteoglycan (HSPG), another major constituent of plaques, greatly fastened the zinc removal with dithizone. The present study has demonstrated the presence of histochemically reactive zinc in plaques, but not preamyloid Abeta deposits, of the Swedish mutant APP transgenic mice. Because preamyloid Abeta deposits fail to develop into congophilic plaques in cerebellum where synaptic vesicle zinc is deficient, the synaptic zinc may be a necessary element in the plaque formation. In holding zinc inside plaques, HSPG may contribute in addition to Abeta.

Accumulation of zinc in degenerating hippocampal neurons of ZnT3-null mice after seizures: evidence against synaptic vesicle origin.

In several brain injury models, zinc accumulates in degenerating neuronal somata. Suggesting that such zinc accumulation may play a causal role in neurodegeneration, zinc chelation attenuates neuronal death. Because histochemically reactive zinc is present in and released from synaptic vesicles of glutamatergic neurons in the forebrain, it was proposed that zinc translocation from presynaptic terminals to postsynaptic neurons may be the mechanism of toxic zinc accumulation. To test this hypothesis, kainate seizure-induced neuronal death was examined in zinc transporter 3 gene (ZnT3)-null mice, a strain that completely lacks histochemically reactive zinc in synaptic vesicles. Intraperitoneal injection of kainate induced seizures to a similar degree in wild type and ZnT3-null mice. Staining of hippocampal sections with a zinc-specific fluorescent dye, N-(6-methoxy-8-quinolyl)-p-carboxybenzoylsulfonamide, revealed that zinc accumulated in degenerating CA1 and CA3 neurons in both groups, indicating that zinc originated from sources other than synaptic vesicles. Injection of CaEDTA into the cerebral ventricle almost completely blocked zinc accumulation in ZnT3-null mice, suggesting that increases in extracellular zinc concentrations may be a critical event for zinc accumulation. Arguing against the possibility that zinc accumulation results from nonspecific breakdown of zinc-containing proteins, injection of kainate into the cerebellum did not induce zinc accumulation in degenerating granule neurons. Taken together, these results support the existing idea that zinc is released into extracellular space and then enters neurons to exert a cytotoxic effect. However, the origin of zinc is not likely to be synaptic vesicles, because zinc accumulation robustly occurs in ZnT3-null mice lacking synaptic vesicle zinc.

Protection by pyruvate against transient forebrain ischemia in rats.

Pyruvate has a remarkable protective effect against zinc neurotoxicity. Because zinc neurotoxicity is likely one of the key mechanisms of ischemic brain injury, the neuroprotective effect of pyruvate was tested in a rat model of transient forebrain ischemia. Control experiments in mouse cortical culture showed that pyruvate almost completely blocked zinc toxicity but did not attenuate calcium-overload neuronal death. Adult rats subjected to 12 min forebrain ischemia exhibited widespread zinc accumulation and neuronal death throughout hippocampus and cortex 72 hr after reperfusion. However, rats injected intraperitoneally with sodium pyruvate (500-1000 mg/kg) within 1 hr after 12 min forebrain ischemia showed almost no neuronal death. In addition, the mortality was markedly decreased in the pyruvate-protected groups (3.8%) compared with the NaCl-injected control group (58.1%). The neuroprotective effect persisted even at 30 d after the insult. The spectacular protection without noticeable side effects makes pyruvate a promising neuroprotectant in human ischemic stroke.

Zn(2+): a novel ionic mediator of neural injury in brain disease.

Zn(2+) is the second most prevalent trace element in the body and is present in particularly large concentrations in the mammalian brain. Although Zn(2+) is a cofactor for many enzymes in all tissues, a unique feature of brain Zn(2+) is its vesicular localization in presynaptic terminals, where its release is dependent on neural activity. Although the physiological significance of synaptic Zn(2+) release is little understood, it probably plays a modulatory role in synaptic transmission. Furthermore, several lines of evidence support the idea that, upon excessive synaptic Zn(2+) release, its accumulation in postsynaptic neurons contributes to the selective neuronal loss that is associated with certain acute conditions, including epilepsy and transient global ischaemia. More speculatively, Zn(2+) dis-homeostasis might also contribute to some degenerative conditions, including Alzheimer's disease. Further elucidation of the pathological actions of Zn(2+) in the brain should result in new therapeutic approaches to these conditions.

Zinc as a paracrine effector in pancreatic islet cell death.

Because of a huge amount of Zn2+ in secretory granules of pancreatic islet beta-cells, Zn2+ released in certain conditions might affect the function or survival of islet cells. We studied potential paracrine effects of endogenous Zn2+ on beta-cell death. Zn2+ induced insulinoma/islet cell death in a dose-dependent manner. Chelation of released endogenous Zn2+ by CaEDTA significantly decreased streptozotocin (STZ)-induced islet cell death in an in vitro culture system simulating in vivo circumstances but not in the conventional culture system. Zn2+ chelation in vivo by continuous CaEDTA infusion significantly decreased the incidence of diabetes after STZ administration. N-(6-methoxy-quinolyl)-para-toluene-sulfonamide staining revealed that Zn2+ was densely deposited in degenerating islet cells 24 h after STZ treatment, which was decreased by CaEDTA infusion. We show here that Zn2+ is not a passive element for insulin storage but an active participant in islet cell death in certain conditions, which in time might contribute to the development of diabetes in aged people.

Characterization of the TSU-PR1 cell line by chromosome painting and flow cytometry.

TSU-PR1 was originally reported as a prostatic carcinoma cell line derived from a lymph node metastasis. Recently, however, this cell line was reported to be derived from T24 bladder carcinoma cells, and thus further definition of its origin is needed. Conventional cytogenetic study of TSU-PR1 showed aneuploidy, ranging from 65 to 86 chromosome with a modal number of 80, and with 10 marker chromosomes, thus conventional cytogenetics cannot be used to determine which chromosomes or regions of chromosomes are critical in cancer development and progression of this cell line. The present study was conducted to characterize genetic changes of the cell line using comparative genomic hybridization (CGH), fluorescence in situ hybridization (FISH), and flow cytometry. CGH results showed that green-to-red fluorescence ratios were within the range of 0.85-1.15, except for a few chromosomes, which reflected near tetraploidy in TSU-PR1. Flow cytometric analysis of TSU-PR1 revealed a DNA index of 3.46n, which is close to the 3.48n calculated from a modal number of 80. The copy numbers of chromosomes 4, 6, 7, 17, and 20 determined by the DNA index and the CGH analyses were 2.85 +/- 0.09, 3.22 +/- 0.77, 3.01 +/- 0.26, 4.05 +/- 0.44, and 4.99 +/- 0.48, respectively. These numbers are also in accordance with the chromosome copy numbers determined with FISH: 2.98 +/- 0.23, 2.91 +/- 0.44, 2.74 +/- 0.44, 3.93 +/- 0.38, and 5.05 +/- 0.78 for chromosomes 4, 6, 7, 17, and 20, respectively (P > 0.05).

Zinc and disease of the brain.

Zinc is one of the most abundant transition metals in the brain. A substantial fraction (10-15%) of brain zinc is located inside presynaptic vesicles of certain glutamatergic terminals in a free or loosely bound state. This vesicle zinc is released with neuronal activity or depolarization, probably serving physiologic functions. However, with excess release, as may occur in a variety of pathologic conditions, zinc may translocate to and accumulate in postsynaptic neurons, events which may contribute to selective neuronal cell death. Intracellular mechanisms of zinc neurotoxicity may include disturbances in energy metabolism, increases in oxidative stress, and activation of apoptosis cascades. Zinc inhibits glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and depletes nicotinamide adenine dinucleotide (NAD(+)) and adenosine triphosphate (ATP). On the other hand, zinc activates protein kinase C (PKC) and extracellular signal-regulated kinase (Erk-1/2), and induces NADPH oxidase; these events result in oxidative neuronal injury. Zinc can also trigger caspase activation and apoptosis via the p75(NTR) pathway. Interestingly, the converse-depletion of intracellular zinc-also induces neuronal death, but in this case, exclusively via classical apoptosis. In addition to the neurotoxic effect, zinc may contribute to the pathogenesis of chronic neurodegenerative disease. For example, in Alzheimer's disease (AD), mature amyloid plaques, but not preamyloid deposits, are found to contain high levels of zinc, suggesting the role of zinc in the process of plaque maturation. Further insights into roles of zinc in brain diseases may help set a new direction toward the development of effective treatments.

Effect of anticonvulsant drugs on glutamate neurotoxicity in cortical cell culture.

Pretreatment with anticonvulsants partially protects animals against the brain damage induced by intraparenchymal injection of kainate, an analogue of the neurotransmitter glutamate. In murine cortical cell culture, high concentrations of phenobarbital, diazepam, phenytoin, or GABA itself did not prevent glutamate-induced neuronal loss. Addition of a glutamate receptor antagonist (gamma-D-glutamyl glycine) did reduce glutamate neurotoxicity. The in vivo protective effect of anticonvulsant drugs against the toxicity of excitatory amino acids must be indirect.

Zinc toxicity on cultured cortical neurons: involvement of N-methyl-D-aspartate receptors.

Neuronal injury induced by the excessive release of endogenous Zn2+ at central glutamatergic synapses may contribute to the pathogenesis of epileptic brain damage. We explored the possibility that N-methyl-D-aspartate receptors might be involved in Zn2+ neurotoxicity. Exposure of murine cortical cell cultures to 300-1000 microM concentrations of Zn2+ for 15 min resulted in widespread neuronal degeneration, accompanied by the release of lactate dehydrogenase to the bathing medium. Both non-competitive and competitive N-methyl-D-aspartate antagonists attenuated this degeneration. However, the participation of N-methyl-D-aspartate receptors in Zn2+ neurotoxicity was atypical. Removal of extracellular Ca2+ attenuated N-methyl-D-aspartate neurotoxicity but potentiated Zn2+ neurotoxicity, whereas increasing extracellular Ca2+ potentiated N-methyl-D-aspartate neurotoxicity but attenuated Zn2+ neurotoxicity. Furthermore, the nature of the antagonism of Zn2+ neurotoxicity induced by N-methyl-D-aspartate antagonists was qualitatively different from that seen with other N-methyl-D-aspartate receptor-mediated events. The block of Zn2+ neurotoxicity induced by the non-competitive N-methyl-D-aspartate antagonist MK-801 was better overcome by increasing Zn2+ concentration than the block induced by the competitive antagonists D-aminophosphonovalerate and CGS-19755. We hypothesize that N-methyl-D-aspartate receptor-gated channels contribute to Zn2+ toxicity by providing a route of Zn2+ influx into neurons. Consistent with this idea, intracellular Zn2+ visualized by the fluorescent Zn2+ chelator, N-(6-methoxy-8-quinolyl)-p-toluenesulfonamide, rose during Zn2+ exposure; this rise was increased by N-methyl-D-aspartate and reduced by either N-methyl-D-aspartate antagonists or high Ca2+.2+ in neuronal cell homeostasis.