Developmental expression, compartmentalization, and possible role in excitotoxicity of a putative NMDA receptor protein in cultured hippocampal neurons.

The mechanisms regulating the expression and localization of excitatory amino acid (EAA) neurotransmitter receptors in neurons of the developing mammalian brain, and roles for these receptors in the plasticity and degeneration of neural circuits are not well understood. We previously isolated and characterized a 71 kDa glutamate binding protein (GBP) from rat brain, and have recently obtained evidence that this GBP is a component of a functional N-methyl-D-aspartate (NMDA) receptor-ion channel complex. We have now used antibodies to this putative NMDA receptor protein to examine its expression and localization, and consequences of its activation in cultured embryonic (18 day) rat hippocampal neurons. Immunocytochemistry and Western blots using monoclonal antibodies to the GBP demonstrated an increase in GBP-positive neurons and their staining intensity with time in culture. GBP was localized to the somata and dendrites of pyramidal-like neurons and was sparse or absent in the axons. The expression and compartmentalization of GBP occurred in isolated neurons indicating that direct cell interactions were not required for these processes. Cell surface staining for GBP occurred in patches on the soma and dendrites. The developmental expression of GBP immunoreactivity closely paralleled the expression of sensitivity to NMDA neurotoxicity. There was a direct relationship between GBP immunoreactivity and neuronal vulnerability to glutamate-induced degeneration; vulnerable neurons stained heavily whereas resistant neurons showed either low levels of staining or no staining. Finally, a GBP antiserum greatly reduced NMDA neurotoxicity (but not kainate neurotoxicity). Taken together, these findings demonstrate the expression of presumptive NMDA receptors within a subpopulation of embryonic hippocampal neurons, and their segregation to the soma and dentrites of pyramidal neurons. This spatial distribution of glutamate receptors among and within neurons is likely to play important roles in regulating the structure of neural circuitry during development, and may also be an important determinant of selective neuronal vulnerability in pathological conditions.     

Muscarinic-receptor antagonist scopolamine rescues hippocampal neurons from death induced by glutamate

Cultured hippocampal neurons were used to test the hypothesis that modulation of muscarine receptors can modify glutamate-induced neurodegeneration. Treatment of hippocampal cultures with scopolamine (1 nM to 1 mM) under glutamate incubation had beneficial effect on neuronal viability. Thus, blockade of muscarinic-receptor sites increased the threshold for glutamate neurotoxicity. These data show that interactions between the NMDA, muscarinic receptors and their corresponding neurotransmitter inputs to hippocampal neurons may play a crucial role in neurodegeneration.     

Agmatine protects against cell damage induced by NMDA and glutamate in cultured hippocampal neurons

Agmatine is a polyamine and has been considered as a novel neurotransmitter or neuromodulator in the central nervous system. In the present study, the neuroprotective effect of agmatine against cell damage caused by N-methyl-D-aspartate (NMDA) and glutamate was investigated in cultured rat hippocampal neurons. Lactate dehydrogenase (LDH) activity assay, beta-tubulin III immunocytochemical staining and terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate (dUTP) nick end-labeling (TUNEL) assay were conducted to detect cell damage. Exposure of 12-day neuronal cultures of rat hippocampus to NMDA or glutamate for 1 h caused a concentration-dependent neurotoxicity, as indicated by the significant increase in released LDH activities. Addition of 100 microM agmatine into media ablated the neurotoxicity induced by NMDA or glutamate, an effect also produced by the specific NMDA receptor antagonist dizocilpine hydrogen maleate (MK801). Arcaine, an analog of agmatine with similar structure as agmatine, fully prevented the NMDA- or glutamate-induced neuronal damage. Spermine and putrescine, the endogenous polyamine and metabolic products of agmatine without the guanidine moiety of agmatine, failed to show this effect, indicating a structural relevance for this neuroprotection. Immunocytochemical staining and TUNEL assay confirmed the findings in the LDH measurement. That is, agmatine and MK801 markedly attenuated NMDA-induced neuronal death and significantly reduced TUNEL-positive cell numbers induced by exposure of cultured hippocampal neurons to NMDA. Taken together, these results demonstrate that agmatine can protect cultured hippocampal neurons from NMDA- or glutamate-induced excitotoxicity, through a possible blockade of the NMDA receptor channels or a potential anti-apoptotic property.     

Damage and plasticity in adult rat hippocampal trisynaptic circuit neurons after neonatal exposure to glutamate excitotoxicity

Hippocampal vulnerability to excitotoxicity has been widely studied along with its implication to learning and memory. Neonatal glutamate excitotoxicity induces loss of CA1 pyramidal neurons in adult rats concomitantly with some plastic changes in the dendritic spines of surviving neurons. At least in part, these may underlie the place learning impairments seen in previous studies based on a similar excitotoxicity-inducing model. In the present study, cytoarchitecture of dentate gyrus, CA3 and CA1 fields were evaluated in 120-day-old rats, after they had been neonatally treated with glutamate as monosodium salt. Dentate granule cells and CA1 pyramidal neurons were less than those counted in NaCl-treated control animals. In addition, dentate granule cells had more dendrites as well as more branched spines. Spine density in CA1 pyramidal neurons was greater than in the controls. Additionally, thin and mushroom spines were proportionally more abundant in monosodium glutamate-treated animals. No effects were seen in the hippocampal CA3 field. Our results strongly suggest a long-term induction of plastic changes in the cytoarchitecture of the hippocampal trisynaptic circuit neurons after cell death provoked by the monosodium glutamate-induced excitotoxicity. These plastic events as well as the aberrant expression of the glutamate NMDA receptors resulting from monosodium glutamate neonatal treatment could be strongly associated with the place learning impairments previously reported.     

Isolated hippocampal neurons in cryopreserved long-term cultures: Development of neuroarchitecture and sensitivity to NMDA

Isolated neurons in long-term culture provide a unique opportunity to address important problems in neuronal development. In the present study we established conditions for cryopreservation and long-term primary culture of isolated embryonic hippocampal neurons. This culture system was then used for initial characterizations of the development of neuroarchitecture and neurotransmitter response systems. Cryoprotection with 8% dimethylsulfoxide, slow freezing, and rapid thawing provided high-yield cultures which appeared normal in terms of cell types, mitotic ability, axonal and dendritic outgrowth, and sensitivity to glutamate neurotoxicity. A reduced medium volume and moderate elevation in extracellular K+ to 20 mM promoted survival of isolated neurons through 3 weeks of culture. The outgrowth of axons and dendrites in pyramidal-like neurons was found to differ over a 3-week culture period such that axons continued to grow at a relatively constant rate while dendritic outgrowth slowed during the second week and ceased by the end of week 3. Developmental changes were also observed in the sensitivity of pyramidal neurons to glutamate neurotoxicity; functional kainate/quisqualate receptors were present during the first week of culture, while responses to N-methyl-D-aspartic acid (NMDA) did not appear until the second week. The technologies for cryopreservation and long-term culture of isolated hippocampal neurons reported here provide a useful system in which to address a variety of problems in development neuroscience.     

Activated microglial cells migrate towards sites of excitotoxic neuronal injury inside organotypic hippocampal slice cultures

The aim of this study was to analyse microglial reactions to excitotoxic N ‐methyl‐ d ‐aspartic acid (NMDA)‐induced degeneration of rat dentate and hippocampal neurons in vitro . We used a migration model combining the techniques of microglial single cell culture and organotypic hippocampal slice culture (OHSC). Site‐specific oxidative damage in OHSCs was induced by pretreatment with 50 μ m NMDA. Neuronal injury determined by propidium iodide (PI) uptake included the hippocampal cell layers of the dentate gyrus (DG) and the cornu ammonis (CA). Fluorescence‐prelabelled microglial cells with ameboid morphology were transferred onto the OHSC and migrated predominantly to the prelesioned cell layers of DG and CA when compared with unlesioned areas of the OHSC. In NMDA pretreated slices, microglial cells clustered around degenerating granule cells in the DG and pyramidal cells in the CA. This effect was significantly inhibited in unlesioned slice cultures and in NMDA‐exposed cultures that were pretreated with the NMDA‐antagonist MK‐801. Our observations suggest that microglia – attracted by the presence of stimuli provided by NMDA‐induced neuronal death – migrate specifically towards these lesioned neurons.     

Cytomegalovirus infection inhibits the expression of N-methyl-d-aspartate receptors in the developing mouse hippocampus and primary neuronal cultures

Cytomegalovirus (CMV) is the most significant infectious cause of developmental brain disorders in humans. The infection occasionally persists and causes neurological disorders. The N-methyl-d-aspartate (NMDA) subtype of glutamate receptors is essential for the development and plasticity of synapses, but also is involved in neuronal excitotoxicity during viral infection. Here we investigated the effects of murine CMV (MCMV) infection on the expression of NMDA receptors in the hippocampal neurons of neonatal mice and primary neuronal cultures. Viral antigen was mostly found in hippocampal pyramidal neurons from the CA1 to CA3. Image analysis of immunohistochemistry demonstrated that the expression of NMDA receptor subunit 1 (NMDA-R1) protein in CA1 neurons of MCMV-infected brain was reduced to 40% of that in uninfected brain. The signal of in situ hybridization for NMDA-R1 mRNA was also decreased in CA1 neurons of MCMV-infected brain. In primary neuronal cultures, reduction of NMDA-R1 expression in MCMV-infected neurons was also detected by immunocytochemistry and Western blotting. These results suggest that reduction of NMDA receptor expression by MCMV infection may cause a decrease in the susceptibility of the neurons to excitotoxic cell death, and may be related to the establishment of viral persistence and functional disturbances in MCMV-infected neurons.     

Selective sparing of hippocampal CA3 cells following in vitro ischemia is due to selective inhibition by acidosis

A brief global ischemic insult to the brain leads to a selective degeneration of the pyramidal neurons in the hippocampal CA1 region while the neurons in the neighbouring CA3 region are spared. The reason for this difference is not known. The selective vulnerability of CA1 neurons to ischemia can be reproduced in vitro in murine organotypic slice cultures, if the ion concentrations in the medium during the anoxic/aglycemic insult are similar to that in the brain extracellular fluid during ischemia in vivo. As acidosis develops during ischemia, we studied the importance of extracellular pH for selective vulnerability. We found that cell death in the CA1 and CA3 regions was equally prevented by removal of calcium from the medium or following blockade of the N-methyl-D-aspartate (NMDA) receptor by D-2 amino-5-phosphonopentanoic-acid (D-APV). On the other hand, damage to the CA3 neurons markedly decreased with decreasing pH following in vitro ischemia, while the degeneration of CA1 neurons was less pH dependent. Patch-clamp recordings from pyramidal neurons in the CA1 and CA3 regions, respectively, revealed a pronounced inhibition of NMDA-receptor mediated excitatory postsynaptic currents (EPSCs) at pH 6.5 that was equally pronounced in the two regions. However, when changing pH from 6.5 to 7.4 the recovery of the EPSCs was significantly slower in the CA3 region. We conclude that acidosis selectively protects CA3 pyramidal neurons during in vitro ischemia, and differentially affects the kinetics of NMDA receptor activation, which may explain the difference in vulnerability between CA1 and CA3 pyramidal neurons to an ischemic insult.     

Selective blockade of non-NMDA receptors does not block rapidly triggered glutamate-induced neuronal death

The quinoxalinedione, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), has been introduced as a relatively selective antagonist of non-N-methyl-D-aspartate (non-NMDA) glutamate receptors. We studied the ability of CNQX to block excitatory amino acid-induced neurotoxicity in murine cortical cell cultures. 100 microM CNQX blocked the acute neuronal swelling induced by 500 microM kainate, but it also attenuated the swelling and degeneration induced by 500 microM NMDA. Addition of 1 mM glycine to the CNQX eliminated antagonism of NMDA toxicity, while preserving antagonism of the neuronal degeneration induced by kainate or AMPA. This selective non-NMDA antagonist combination of CNQX plus glycine substantially attenuated the acute neuronal swelling induced by brief exposure to 500 microM glutamate, but had little effect on subsequent late degeneration, supporting the conclusion that rapidly triggered glutamate-induced cortical neuronal death is predominantly mediated by NMDA receptors.     

Direct observation of the agonist-specific regional vulnerability to glutamate, NMDA, and kainate neurotoxicity in organotypic hippocampal cultures.

Excessive activation of excitatory amino acid receptors has been implicated in the neuronal degeneration caused by ischemia, hypoglycemia, and prolonged seizures. We have observed directly the time course and regional vulnerability of hippocampal neurons to glutamate receptor-mediated injury in organotypic hippocampal cultures, a preparation which combines accessibility and long-term survival with preservation of regional differentiation and neuroanatomic organization. Cultures were incubated with the fluorescent dye propidium iodide which selectively enters and stains cells only after membrane damage. After 5 to 10 min of a 30-min exposure to kainate (100 microM), large neurons in the hilus of the dentate were first to become brightly fluorescent. Propidium staining subsequently appeared in the other regions of the hippocampus and increased to a maximum over the first 6 h of recovery. NMDA (10 microM) caused propidium staining that was limited to CA1 and the dentate gyrus of the cultures, sparing CA3, consistent with the regions of highest NMDA receptor density in vivo. Glutamate (1 mM) caused a delayed, progressive pattern of staining that began in CA1 (2 to 4 h after exposure), then extended to include CA3 and finally the dentate gyrus over the next 24 h. Release of LDH activity into the media was slower and less sensitive than propidium staining. Histologic degeneration was limited to neurons 24 h after agonist exposure and was consistent with the propidium staining. NMDA, kainate, and glutamate each produced a unique pattern of neuronal injury. Most notably, glutamate had low potency as a toxin and its pattern of neuronal injury was not reproduced by NMDA.     

Post-insult exposure to (+/-) kavain potentiates N-methyl-D-aspartate toxicity in the developing hippocampus

Kavapyrone extracts of the pepper plant Piper methysticum Forst. have been reported to be pharmacologically active in the brain by modulating the function of several ionotropic receptor systems and voltage-sensitive ion channels. While kavapyrones have previously demonstrated neuroprotective effects against several forms of neurotoxicity, the possibility remains that perturbed function of neuronal ion transport may prove to be neurotoxic in some instances. The present studies were designed to examine the effects of the kavapyrone, (+/-) kavain, on viability of organotypic hippocampal explants exposed to the excitotoxin N-methyl-D-aspartate (NMDA). Exposure to (+/-) kavain (1-600 microM) for 24 h did not alter neuronal viability in the CA1, CA3, or dentate gyrus regions of hippocampal explants. However, higher concentrations of (+/-) kavain (> or =300 microM) produced marked neurotoxicity in the lacunosum moleculare layer of the hippocampus. One hour of exposure to NMDA (20 microM) produced significant neuronal death in both the CA3 and CA1 pyramidal cell regions, effects prevented by co-exposure to MK-801 (30 microM). Co-exposure of explants to (+/-) kavain (1-100 microM) with NMDA did not alter the severity of NMDA-induced neurotoxicity. However, exposure of NMDA-treated explants to (+/-) kavain (> or =10 microM) for 24 h after insult produced significant increases in neurotoxicity in the CA1 and dentate gyrus regions of explants. In conclusion, while the kavapyrone (+/-) kavain is neurotoxic only at high concentrations when exposed alone to the developing hippocampus, it appears to adversely affect neuronal recovery following excitotoxic insults.     

Zinc alters excitatory amino acid neurotoxicity on cortical neurons

Recent studies have suggested that large amounts of free zinc may be coreleased during excitatory synaptic transmission at glutamatergic synapses, and may act postsynaptically to decrease actions mediated by N-methyl-D-aspartate (NMDA) receptors, while often increasing neuroexcitation mediated by quisqualate receptors. The present study examined the ability of zinc to alter excitatory amino acid (EAA) neurotoxicity. Murine cortical cell cultures were exposed to EAAs for 5 min in defined solutions, and neuronal cell injury was examined the following day both morphologically and by lactate dehydrogenase assay. Inclusion of 30-500 microM zinc in the exposure solution produced a zinc concentration-dependent, noncompetitive attenuation of NMDA-induced neuronal injury, with an ED50 of about 80 microM. In contrast, zinc produced the same concentration-dependent potentiation of quisqualate neurotoxicity; and with 500 microM zinc, a small potentiation of kainate neurotoxicity was suggested. The effect of zinc on the neurotoxicity of the broad-spectrum agonist glutamate was consistent with these effects on specific agonists, as well as with a previous study showing that glutamate neurotoxicity normally depends predominantly on NMDA-receptor activation. Zinc produced a concentration-dependent reduction in glutamate-induced neuronal injury in a fashion similar to that seen with NMDA, but less effectively. In addition, despite this overall protective effect, zinc paradoxically increased the glutamate-induced destruction of nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-d)-containing neurons, a subpopulation that was shown in the preceding paper (Koh and Choi, 1988) to exhibit resistance to NMDA receptor-mediated neurotoxicity, and vulnerability to non-NMDA receptor-mediated neurotoxicity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacology of glutamate neurotoxicity in cortical cell culture: attenuation by NMDA antagonists

The antagonist pharmacology of glutamate neurotoxicity was quantitatively examined in murine cortical cell cultures. Addition of 1-3 mM DL-2-amino-5-phosphonovalerate (APV), or its active isomer D-APV, acutely to the exposure solution selectively blocked the neuroexcitation and neuronal cell selectively blocked the neuroexcitation and neuronal cell loss produced by N-methyl-D-aspartate (NMDA), with relatively little effect on that produced by either kainate or quisqualate. As expected, this selective NMDA receptor blockade only partially reduced the neuroexcitation or acute neuronal swelling produced by the broad-spectrum agonist glutamate; surprisingly, however, this blockade was sufficient to reduce glutamate-induced neuronal cell loss markedly. Lower concentrations of APV or D-APV had much less protective effect, suggesting that the blockade of a large number of NMDA receptors was required to acutely antagonize glutamate neurotoxicity. This requirement may be caused by the amplification of small amounts of acute glutamate-induced injury by subsequent release of endogenous NMDA agonists from injured neurons, as the "late" addition of 10-1000 microM APV or D-APV (after termination of glutamate exposure) also reduced resultant neuronal damage. If APV or D-APV were present both during and after glutamate exposure, a summation dose-protection relationship was obtained, showing substantial protective efficacy at low micromolar antagonist concentrations. Screening of several other excitatory amino acid antagonists confirmed that the ability to antagonize glutamate neurotoxicity might correlate with ability to block NMDA-induced neuroexcitation: The reported NMDA antagonists ketamine and DL-2-amino-7-phosphono-heptanoate, as well as the broad-spectrum antagonist kynurenate, were all found to attenuate glutamate neurotoxicity substantially; whereas gamma-D-glutamylaminomethyl sulfonate and L-glutamate diethyl ester, compounds reported to block predominantly quisqualate or kainate receptors, did not affect glutamate neurotoxicity. The present study suggests that glutamate neurotoxicity may be predominantly mediated by the activation of the NMDA subclass of glutamate receptors--occurring both directly, during exposure to exogenous compound, and indirectly, due to the subsequent release of endogenous NMDA agonists. Given other studies linking NMDA receptors to channels with unusually high calcium permeability, this suggestion is consistent with previous data showing that glutamate neurotoxicity depends heavily on extracellular calcium.     

Phenformin suppresses calcium responses to glutamate and protects hippocampal neurons against excitotoxicity

Phenformin is a biguanide compound that can modulate glucose metabolism and promote weight loss and is therefore used to treat patients with type-2 diabetes. While phenformin may indirectly affect neurons by changing peripheral energy metabolism, the possibility that it directly affects neurons has not been examined. We now report that phenformin suppresses responses of hippocampal neurons to glutamate and decreases their vulnerability to excitotoxicity. Pretreatment of embryonic rat hippocampal cell cultures with phenformin protected neurons against glutamate-induced death, which was correlated with reduced calcium responses to glutamate. Immunoblot analyses showed that levels of the N-methyl-d-aspartate (NMDA) subunits NR1 and NR2A were significantly decreased in neurons exposed to phenformin, whereas levels of the AMPA receptor subunit GluR1 were unchanged. Whole-cell patch clamp analyses revealed that NMDA-induced currents were decreased, and AMPA-induced currents were unchanged in neurons pretreated with phenformin. Our data demonstrate that phenformin can protect neurons against excitotoxicity by differentially modulating levels of NMDA receptor subunits in a manner that decreases glutamate-induced calcium influx. These findings show that phenformin can modulate neuronal responses to glutamate, and suggest possible use of phenformin and related compounds in the prevention and/or treatment of neurodegenerative conditions.     

Neuroprotection against NMDA excitotoxicity by group I metabotropic glutamate receptors is associated with reduction of NMDA stimulated currents

The neurotransmitter glutamate can have both excitotoxic and protective effects on neurons. The excitotoxic effects have been intensively studied, whereas the protective effects, including the involvement of metabotropic glutamate receptors (mGluRs), remain unclear. In the present study, we tested the protective effects of the group-I-mGluR agonist (S)-3,5-dihydroxyphenylglycine (DHPG) on organotypic hippocampal slice cultures exposed to excitotoxic concentrations of N-methyl-D-aspartate (NMDA). Effects of DHPG on electrophysiological responses induced by NMDA receptor activation were also recorded. Experiments were performed on organotypic hippocampal slice cultures derived from 7-day-old rats, with cellular uptake of propidium iodide as a marker for neuronal cell death. Slice cultures pretreated with DHPG (10 or 100 microM) for 2 h prior to exposure to 50 microM NMDA for 30 min displayed reduced propidium iodide uptake, compared to cultures exposed to NMDA only. The neuroprotective effect was confirmed by Hoechst 33342 staining, where the appearance of pycnotic nuclei after NMDA treatment was prevented by the DHPG pretreatment. Using caspase-3 activity to monitor the presence of apoptosis, failed to demonstrate this type of cell death in CA1 after NMDA application. The protective effect of DHPG was abolished by the mGluR1 selective antagonist (S)-(+)-alpha-amino-4-carboxy-2-methylbenzeneacetic acid (LY367385; 5 or 10 microM), whereas the mGluR5-selective antagonist 2-methyl-6-phenylethynylpyridine (MPEP; 1 microM) had no effect. Voltage-clamping of CA1 pyramidal cells in cultures treated with 10 microM DHPG for 2 h showed a significant depression of NMDA-induced inward currents compared to untreated controls. We conclude that neuroprotection induced by activation of group-I-mGluRs involve mGluR1 and is associated with decreased NMDA-stimulated currents.     

Roles for mitotic history in the generation and degeneration of hippocampal neuroarchitecture

The mechanisms regulating the highly ordered neuroarchitecture of the mammalian brain are largely unknown. The present study took advantage of hippocampal pyramidal-like neurons that arose from a common progenitor cell in cell culture (sister neurons) to ascertain the contribution of intrinsic factors to both the generation and degeneration of neuroarchitecture. Sister neurons were similar in overall cell form and dendritic numbers and lengths. Control non-sister neurons that grew in contact did not generate similar morphologies, indicating that the similarity of sister cells did not result from influences of the local microenvironment or cell interactions. These results suggest that intrinsic factors related to mitotic history play a role in the generation of neuroarchitecture. Since particular groups of hippocampal neurons are sensitive to glutamate neurotoxicity in situ and are vulnerable in neurodegenerative disorders, it was of interest to test glutamate sensitivity in the neuronal population and in mitotic sister neurons. A subpopulation of pyramidal neurons was sensitive to glutamate neurotoxicity. A striking finding was that sister neurons were invariably either both sensitive or both resistant to glutamate, while non-sister neurons often showed different responses to glutamate. Pharmacological studies indicated that glutamate neurotoxicity was mediated by kainate/quisqualate type receptors by a mechanism involving calcium influx through membrane channels. Fura-2 measurements of intracellular calcium revealed that sister neurons had similar rest levels of calcium and, strikingly, glutamate caused a dramatic increase in intracellular calcium levels only in neurons which subsequently degenerated. Apparently, intrinsic differences in sensitivity to glutamate lie at a point prior to calcium entry, probably at the level of glutamate receptors. Taken together, these results indicate that the mitotic history of a neuron can determine its presence and potential for connectivity as well as its susceptibility to neurodegeneration.     

Cytotoxic effect of glutamate and its agonists on mouse hippocampal neurons

The neurodegenerative action of the excitatory amino acid neurotransmitter (glutamate) and its exogenous (N-methyl-D-aspartate, kainate) or endogenous (quinolinate) analogues were studied on cultures of dissociated nerve cells from the embryonal mouse hippocampus. The exposure of primary cultures for 3-6 h to these excitotoxins showed that neurons were vulnerable to both glutamate and all tested agonists which induced the swelling and vacuolization of neuronal bodies accompanied by degeneration of their dendrites. This process terminated by complete cell destruction. The neurotoxic effect of glutamate (1 mM) was not suppressed by a competitive NMDA receptor antagonist (D, L-2-amino-5-phosphonovalerate, 0.3 mM) and was only slightly prevented by gamma-D-glutamylglycine (3mM). The protective action of the latter was more evident in the presence of lower glutamate concentration (0.5 mM). The excitotoxic effect of N-methyl-D-aspartate (0.1 mM) or quinolinate (0.5mM) was almost completely blocked by both antagonists. In contrast, D, L-2-amino-5-phosphonovalerate failed to protect hippocampal neurons from damage induced by kainate while partial antagonism of kainate neurotoxicity was observed with gamma-D-glutamylglycine. These finding suggest that glutamate neurotoxicity may be derived, mainly, from the non-NMDA type(s) of glutamate receptor present on hippocampal cell membranes with a low effectiveness to suppress this effect by selective competitive NMDA antagonist. Possible involvement of glutamate receptor(s) in the early dendritic outgrowth of hippocampal neurons and in the process of neuronal "cell death" is discussed.     

Differential expressions of glycine transporter 1 and three glutamate transporter mRNA in the hippocampus of gerbils with transient forebrain ischemia.

The extracellular concentrations of glutamate and its co-agonist for the N-methyl-d-aspartate (NMDA) receptor, glycine, may be under the control of amino acid transporters in the ischemic brain. However, there is little information on changes in glycine and glutamate transporters in the hippocampal CA1 field of gerbils with transient forebrain ischemia. This study investigated the spatial and temporal expressions of glycine transporter 1 (GLYT1) and three glutamate transporter (excitatory amino acid carrier 1, EAAC1; glutamate/aspartate transporter, GLAST; glutamate transporter 1, GLT1) mRNA in the gerbil hippocampus after 3 minutes of ischemia. The GLYT1 mRNA was transiently upregulated by the second day after ischemia in astrocytelike cells in close vicinity to hippocampal CA1 pyramidal neurons, possibly to reduce glycine concentration in the local extracellular spaces. The EAAC1 mRNA was abundantly expressed in almost all pyramidal neurons and dentate granule cells in the control gerbil hippocampus, whereas the expression level in CA1 pyramidal neurons started to decrease by the fourth day after ischemia in synchrony with degeneration of the CA1 neurons. The GLAST and GLT1 mRNA were rather intensely expressed in the dentate gyrus and CA3 field of the control hippocampus, respectively, but they were weakly expressed in the CA1 field before and after ischemia. As GLAST and GLT1 play a major role in the control of extracellular glutamate concentration, the paucity of these transporters in the CA1 field may account for the vulnerability of CA1 neurons to ischemia, provided that the functional GLAST and GLT1 proteins are also less in the CA1 field than in the CA3 field. This study suggests that the amino acid transporters play pivotal roles in the process of delayed neuronal death in the hippocampal CA1 field.     

Dearth of glutamate transporters contributes to striatal excitotoxicity

Since excitotoxicity is hypothesized to contribute to cell death in Huntington's disease (HD), we examined the susceptibility of striatal and hippocampal neurons to glutamate-induced cell death. Striatal cultures were more susceptible to glutamate-triggered toxicity than sister hippocampal cultures. Dose-response curves were equivalent when secondary toxicity was blocked with application of the NMDA receptor antagonist, MK801, or enhanced with the pan-specific glutamate transport blocker, TBOA, following excitotoxin removal. TBOA failed to alter the dose-response characteristics of striatal excitotoxicity, ruling out reverse operation of glutamate transporters. Striatal cultures expressed less EAAC1 and less membrane-associated EAAC1, GLT1, and GLAST than hippocampal cultures. Antisense down-regulation of EAAC1 increased the sensitivity of hippocampal cultures to glutamate, indicating that this transporter can act as an important neuroprotectant. Thus, the relative expression levels of glutamate transporters, even in parts of the brain where they are considered adequately expressed, appear to influence the sensitivities of different neuronal populations to excitotoxicity.     

Neurotoxic and neuroprotective effects of glutamate are enhanced by introduction of amyloid precursor protein cDNA

The physiological role of amyloid precursor protein (APP), whose anomalous metabolite is a putative pathogen for Alzheimer disease, remains unclear. From the enhanced responsiveness to glutamate in cultured hippocampal neurons after the introduction of cDNA of APP695 (an isoform of APP dominant in human brain) using an adenovirus vector, we have recently raised the hypothesis that APP modulates neuronal sensitivity to glutamate. To test this hypothesis, we utilized here the unique effects of glutamate on the survival of different types of neurons. It is known that hippocampal neurons undergo deterioration in 24 h after application of glutamate in a dose-dependent manner. This vulnerability was increased in the cells transfected with adenovirus carrying cDNA of APP695. By contrast, it is known that cerebellar granule neurons require for their survival the supplementation of NMDA to the medium. The dose of NMDA required for survival was reduced after the transfection of the APP-adenovirus to cerebellar granule neurons. These enhancing effects of APP on the glutamate-induced vulnerability in hippocampal neurons and the glutamate (NMDA)-dependent survival in cerebellar neurons were blocked by glutamate receptor inhibitors, and were not seen after application of a control adenovirus carrying cDNA of beta-galactosidase. Since the effects of glutamate were enhanced in both directions, the hypothesis became more likely that one of the physiological functions of cellular APP is the regulation of glutamate receptors.