Differential vulnerabilities of substantia nigra catecholamine neurons to excitatory amino acid-induced degeneration in rat midbrain slices

Although differential vulnerability in different regions of the central nervous system is a characteristic feature of neurodegenerative disorders in vivo, its cellular basis is not well understood. In the present study we investigated whether catecholamine neurons in different regions of the substantia nigra (SN) are differentially vulnerable to excitatory amino acid-induced damage in a midbrain slice preparation. Rats were anesthetized by halothane inhalation and killed, the brain was rapidly removed, and 300-microm-thick midbrain slices were cut horizontally on a vibratome. The slices were incubated at 35 degrees C for 2 h in saline buffer containing either kainic acid (KA) or N-methyl-d-aspartate (NMDA) (10-50 microM). They were then fixed and cut into 30-microm sections that were coplanar with the horizontal slice. Individual catecholamine neurons were identified in these thin sections using an antibody to tyrosine hydroxylase coupled to diaminobenzidine. Catecholaminergic neurons in the dorsal and ventral tiers of the SN were readily identified by reference to an atlas of the distribution of catecholamine neurons in the horizontal plane. Using dendritic degeneration as a sensitive index of damage, and submaximal concentrations of KA and NMDA, we found that catecholamine neurons in the dorsal tier were more vulnerable than those in the ventral tier. For example, KA (10 microM) caused a significant reduction in the proportion of neurons with dendrites in the dorsal tier (from 60 to 34%) without altering the dendritic arbor of ventral tier neurons. After treatment with 50 microM KA, only 11% of dorsal tier neurons retained any dendrites while 45% of ventral tier neurons retained their dendrites. These differences were statistically significant (P<0.001). A similar differential vulnerability was apparent in slices treated with NMDA; neurons in the dorsal tier lost dendrites before detectable damage in the ventral tier. An understanding of the comparative anatomical, neurochemical, and physiological properties of vulnerable (dorsal tier) and resistant (ventral tier) catecholamine neurons in rat SN may provide significant insights into the mechanisms and treatment of neurodegenerative disorders involving catecholamine neurons.     

Degeneration of the Dendritic Arbor as an Index of Neurotoxicity in Identified Catecholamine Neurons in Rat Brain Slices

Although catecholamine neurons are vulnerable targets for neurotoxins and degenerative disease, fewin vitrostudies have investigated the mechanisms of neurodegeneration in these cells. We therefore developed a brain slice preparation for this purpose. Rats were killed by cervical dislocation and 400-μm-thick horizontal slices containing midbrain catecholamine neurons were incubated for 2 h in the presence or absence of kainic acid (KA, 50 μM). After fixation, the slices were recut by a technique that provided thin (40 μm) sections in the same plane as the parent slice. Catecholamine neurons in these coplanar sections were labeled by immunostaining for tyrosine hydroxylase (TH) coupled with diaminobenzidine. The topographical organization of the horizontal plane of the brain was retained in the coplanar sections, enabling precise identification of catecholamine neurons in the thin sections, by reference to an atlas in the horizontal plane. In this study we examined neurons in the substantia nigra (SN). A key feature of the immunostaining was that it revealed both the cell body and also the extensive dendritic projections of SN neurons in the horizontal plane. After treatment with KA, cell bodies remained intact but the dendrites were truncated or fragmented. The loss of dendrites is a sensitive and readily quantifiable indicator of damage. KA caused significant reductions in the proportion of SN neurons with intact dendrites and in the total length of the dendrites, measured using a computer program. The sensitive index of damage and the facility to clearly distinguish catecholamine groups that are topographically close yet functionally distinct are the principal features of the experimental approach that we have developed. The preparation offers major advantages for investigating the selective vulnerability or resistance of particular types of catecholamine neurons to damage.     

Excitatory Amino Acid-Induced Degeneration of Dendrites of Catecholamine Neurons in Rat Substantia Nigra

We have recently established a rat substantia nigra (SN) slice preparation in which a sensitive index of excitatory amino acid (EAA) toxicity was degeneration of the dendritic arbor of catecholamine neurons labelled by immunostaining for tyrosine hydroxylase (TH). The present study examined the pharmacological characteristics of EAA-induced neurotoxicity. Rats were anesthetised by halothane inhalation and killed, the brain was rapidly removed, and 400-μm-thick SN slices cut in the horizontal plane on a vibratome. Slices were incubated in saline buffer at 35°C for 15 min to 6 h in the presence or absence or absence of kainic acid (KA) orN-methyl- -aspartate (NMDA) in concentrations ranging from 10 to 500 μM. The slices were then fixed and resectioned into 40-μm sections that were coplanar with the parent slice. Dopaminergic SN neurons were labeled using antibody to tyrosine hydroxylase (TH) coupled to diaminobenzidine. A feature of the immunostaining was that it labeled not only the cell body but also the prolific dendritic arborization of SN neurons. Dendritic damage was quantified by counting the proportion of neurons with intact dendrites after treatment with EAA. KA and NMDA caused loss of dendrites that was prevented by CNQX (20 μM) and MK-801 (20 μM), respectively, indicating that activation of either NMDA or non-NMDA receptors produces neurotoxicity. EAA-induced dendritic damage was observed within 2 h of treatment with a low concentration (10 μM) of KA and within 15 min if the concentration was increased to 500 μM. Thus the loss of dendrites occurs rapidly and precedes disintegration of the cell bodies. Furthermore, brief (15 min) exposure to EAA initiated damage in the dendrites which progressed after the EAA was removed from its receptor. The observations are consistent with the postulated role of EAAs in neurodegenerative diseases. Labeling the dendritic arbor provides a sensitive approach to investigating the cellular mechanisms of neurodegeneration of catecholamine neurons.     

Mitochondrial complex inhibitors preferentially damage substantia nigra dopamine neurons in rat brain slices

Using a rat brain slice preparation, we investigated the role of energy impairment on the selective loss of dopamine neurons in the substantia nigra (SN). Brain slices (400 microm) were incubated at 35 degrees C for 2 h in the presence or absence of mitochondrial complex inhibitors, rotenone, MPP+, 3-nitropropionic acid, and antimycin A. Slices were also incubated in rotenone with excitatory amino acid (EAA) receptor antagonists, MK-801 and CNQX, to determine whether rotenone-induced damage was mediated by EAAs. The slices were then fixed, recut into 30-microm sections, and immunolabeled for tyrosine hydroxylase (TH) to identify catecholamine neurons and to quantify loss of TH-labeled dendrites after treatment. Quantitative comparison was made between SN dopamine neurons, in which rotenone-induced dendrite loss was severe, and hypothalamic A11 dopamine neurons, which were spared. Adjacent sections that were immunolabeled for calbindin or stained with cresyl violet also revealed a striking dendritic degeneration of SN neurons in rotenone-exposed slices, whereas noncatecholamine neurons, such as those in the perifornical nucleus (PeF), were more resistant. Preferential damage to SN dopamine neurons was also evident with other mitochondrial complex inhibitors, MPP+ and antimycin A. EAA receptor antagonists provided partial protection to SN neurons in slices incubated with rotenone (3 microM). The particular vulnerability of SN dopamine neurons in the slice is consistent with the vulnerability of SN in Parkinson's disease. The selective effect of mitochondrial complex inhibition in SN dopamine neurons implies a fundamental deficit in the capacity of these neurons to defend against toxic insult.     

Differential responses of rat cerebral somatostatinergic and cholinergic cells to glutamate agonists

Reductions in cortical somatostatin (SRIH) and choline acetyltransferase (ChAT) are major biochemical deficits in Alzheimer disease (AD). SRIH and ChAT were measured in fetal rat cerebral neurons after exposure to the glutamate agonistsN-methyl-d-aspartate (NMDA), kainate (KA), and quisqualate (Q). NMDA (96 h incubation) stimulated SRIH release and content in a dose-dependent manner with aB _max of 10^?5 M and EC₅₀ of 2?3×10^?6 M. KA showed a small stimulation in SRIH levels at 10^?5 M, but produced marked inhibition at 10^?4 M. Q decreased both intracellular and secreted SRIH. KA (51–76% of basal) and Q (27–56% of basal) but not NMDA (91–114% of basal) also inhibited the incorporation of [³⁵S]methionine into proteins. In similar experiments 10^?4 M Q (23±9% of basal) and KA (20±3% of basal) but not NMDA (80±16% of basal) reduced ChAT levels in hypothalamic/septal cultures. These inhibitory actions on ChAT activity by KA and Q were reversed by γ-glutamyltaurine (GT) but not by 2-amino-5-phosphonopentanoic acid (AP5). Chronic NMDA exposure partially inhibited muscarinic acetylcholine receptor (mAChR) mediated inositol phospholipid (PI) turnover, whereas it was abolished after KA and Q pretreatment. These findings suggest that in cerebral cell cultures, NMDA has a stimulatory action on somatostatinergic neurons and non-NMDA receptor agonism could play an important role in EAA-mediated neural damage.     

Melanin, tyrosine hydroxylase, calbindin and substance P in the human midbrain and substantia nigra in relation to nigrostriatal projections and differential neuronal susceptibility in Parkinson's disease.

The anatomy of melanin-containing neurons and other midbrain structures was examined by tyrosine hydroxylase (TH), calbindin D28k, and substance P immunostaining. Greater than 95% of cells in the substantia nigra pars compacta contained melanin, but densely packed cells in a ventral tier had a low content of melanin and loosely packed cells in a dorsal tier had a high content of melanin. Approximately 60% in the gamma group and 40% in the retrorubral nucleus had a low content of melanin. TH immunostaining was moderate in both the ventral and dorsal tiers, but more intense in the gamma group and retrorubral nucleus. Calbindin D28k was absent from the ventral and dorsal tiers, but present in the gamma group and retrorubral nucleus. In the light of primate tracing studies these findings suggest that the ventral tier of the pars compacta projects to striosomes of the striatum and the dorsal tier, gamma group and retrorubral nucleus to the matrix compartment. The ventral tier is more vulnerable than the dorsal tier in Parkinson's disease, but the cells contain less melanin. Neither tier contains calbindin D28k. This differential vulnerability between the ventral and dorsal tiers cannot be explained by melanin or calbindin D28k.     

Neurotoxic Effects of Kainic Acid on Substantia Nigra Neurons in Rat Brain Slices

Excitatory amino acids (EAAs) have been implicated as mediators of cell death in neurodegenerative diseases involving catecholamine neurons. Few studies, however, have examined the toxic effects of EAAs on identified catecholamine neuronsin vitro.We have investigated the neurotoxic effects of kainic acid in a rat brain substantia nigra (SN) slice preparation. Rats (60–80 g) were anesthetised with halothane and killed by cervical dislocation. SN slices, 300 μm thick, were incubated at 35°C in a modified Krebs solution in the presence or absence of kainic acid and then fixed and processed for either immunohistochemistry (IHC) or electron microscopy (EM). In IHC experiments, SN neurons were labeled using antibody to tyrosine hydroxylase (TH) coupled to diaminobenzidine. In control slices, the antibody labeled not only the cell body but also the prolific dendritic arbor of SN neurons. Treatment with 50 μMkainic acid for 15 min or 2 h resulted in loss of TH staining and apparent fragmentation of the dendrites. EM provided ultrastructural evidence for kainic acid-induced degeneration of the dendritic arbor of SN neurons. Typically, the dendritic membrane was broken, or diffuse and collapsed. Ultrastructural damage, including clumping and marginalization of chromatin and vacuolation of the cytoplasm, was also observed in cell bodies. Damage to the dendritic arbor may occur early in the neurotoxic events leading to cell death, preceding the loss of the cell body. Our observations are consistent with the postulated role of EAAs as mediators of catecholamine neuron death.     

Cyclic adenosine 3'5'-monophosphate potentiates excitatory amino acid and synaptic responses of rat spinal dorsal horn neurons.

Intracellular recordings were made from rat dorsal horn neurons in the in vitro slice preparation to study the actions of cyclic adenosine 3',5'-monophosphate (cyclic AMP). In the presence of TTX, bath application of the membrane permeable analogue of cyclic AMP, 8-Br cyclic AMP (25-100 microM) caused a small depolarization of the resting membrane potential accompanied by a variable change in membrane input resistance. In addition, 8-Br cyclic AMP caused a long-lasting increase in the spontaneous synaptic activity and the amplitude of presumed monosynaptic excitatory postsynaptic potentials evoked in the substantia gelatinosa neurons by orthodromic stimulation of a lumbar dorsal root. When the fast voltage-sensitive Na conductance was blocked by TTX, 8-Br cyclic AMP enhanced in a reversible manner, the depolarizing responses of a proportion of dorsal horn neurons to N-methyl-D-aspartic acid (NMDA), alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA), quisqualic acid (QA) and kainic acid (KA). The effects of 8-Br cyclic AMP on the resting membrane potential and the NMDA response of dorsal horn neurons were mimicked by reducing phosphodiesterase activity with bath application of 3-isobutyl-1-methylxanthine, but not by cyclic AMP applied extracellularly. Moreover, we have found that intracellular application of a protein inhibitor of cyclic AMP-dependent protein kinase (PKI) into dorsal horn neurons prevents the 8-Br cyclic AMP-induced potentiation of the NMDA response of these cells. These results suggest that in the rat spinal dorsal horn the activation of the adenylate cyclase-cyclic AMP-dependent protein kinase system may be involved in the enhancement of the sensitivity of postsynaptic excitatory amino acid (NMDA, AMPA, KA) receptors and modulation of primary afferent neurotransmission, including nociception.     

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.     

Excitotoxic degeneration of hypothalamic orexin neurons in slice culture

Several lines of evidence indicate that narcolepsy, a sleep disorder, results from the loss of hypothalamic orexin (hypocretin)-containing neurons, but the mechanisms responsible for selective elimination of this neuronal population are unknown. Using organotypic rat hypothalamic slice cultures, we investigated vulnerability of orexin neurons to excitotoxic insults. Twenty-four hours of incubation with N-methyl-D-aspartate (NMDA) followed by a recovery period of 72 h resulted in a marked decrease in the number of orexin-immunoreactive neurons, whereas melanin-concentrating hormone (MCH)-immunoreactive neurons in the same cultures were relatively spared. In contrast, orexin neurons were more resistant to kainic acid cytotoxicity than MCH neurons. Examinations of the effects of several endogenous glutamate receptor agonists as well as a glutamate transporter blocker highlighted quinolinic acid as an endogenous excitotoxin that could cause selective loss of orexin neurons as compared to MCH neurons by activating NMDA receptors. In addition, quinolinic acid-induced decrease of orexin neurons was prevented by an inhibitor of poly(ADP-ribose) polymerases. These results provide the first evidence concerning cytotoxic consequences onto orexin neurons, and indicate that NMDA receptor-mediated injury may contribute to the selective loss of these neurons in the hypothalamus, a prominent neuropathological feature found in narcolepsy patients.     

Inverse relationship between the contents of neuromelanin pigment and the vesicular monoamine transporter-2: human midbrain dopamine neurons

The dopaminergic neurons in the ventral substantia nigra (SN) are significantly more vulnerable to degeneration in Parkinson's disease (PD) than the dopaminergic neurons in the ventral tegmental area (VTA). The ventral SN neurons also contain significantly more neuromelanin pigment than the dopaminergic neurons in the VTA. In vitro data indicate that neuromelanin pigment is formed from the excess cytosolic catecholamine that is not accumulated into synaptic vesicles by the vesicular monoamine transporter-2 (VMAT2). By using quantitative immunohistochemical methods in human postmortem brain, we sought to examine the relative contents of VMAT2 within neurons that contain different amounts of neuromelanin pigment. The immunostaining intensity (ISI) was measured for VMAT2 and also for the rate-limiting enzyme for the synthesis of dopamine, tyrosine hydroxylase (TH). ISI measures were taken from the ventral SN region where neurons are most vulnerable to degeneration in PD, nigrosome-1 (N1); from the ventral SN region where cells are moderately vulnerable to degeneration in PD, the matrix (M); and from VTA neurons near the exit of the third nerve (subregion III). The data indicate that 1) subregion III neurons have significantly higher levels of VMAT2 ISI compared with N1 neurons (more than twofold) and M neurons (45%); 2) there is an inverse relationship between VMAT2 ISI and neuromelanin pigment in the N1 and III neurons; 3) there is an inverse relationship between VMAT2 ISI and the vulnerability to degeneration in PD in the N1, M, and III subregions; and 4) neurons with high VMAT2 ISI also have high TH ISI. These data support the hypothesis that midbrain dopaminergic neurons that synthesize greater amounts of dopamine have more vesicular storage capacity for action potential-induced release of transmitter and that the ventral SN neurons accumulate the most neuromelanin pigment, in part because they have the least VMAT2 protein.     

NMDA, kainate, and AMPA depolarize nondopamine neurons in the rat ventral tegmentum

The possible existence of N-methyl-d-aspartate (NMDA) and non-NMDA receptors on electrophysiologically identified nondopamine neurones in the ventral tegmental area (VTA) was tested in rat midbrain slice preparations. NMDA, kainate (KA), and AMPA (α-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid) depolarized the membrane potential of nondopamine neurons in a dose-dependent manner. The NMDA effect was blocked by the selective NMDA receptor antagonist, CGS 19755 (cis-4-phosphonomethyl-2-piperidine carboxylate), but not by the non-NMDA receptor antagonist, NBOX [2,3-dihydroxy-6-nitro-7-sulfamoyl-benzo(F)quinoxaline]. In contrast, the effects of KA and AMPA were antagonized by NBOX, but not by CGS 19755. The rank order potency of the three agonists was AMPA > KA > NMDA, with thresholds of 0.1, 0.3, and 3 μM, respectively. These results provide clear electrophysiological evidence that nondopamine neurons in the ventral tegmental area possess both NMDA and non-NMDA receptors.     

Different receptors mediate motor neuron death induced by short and long exposures to excitotoxicity

We compared the effect of short and long exposures of cultured motor neurons to glutamate and kainate (KA) and studied the receptors involved in these two types of excitotoxicity. There was no difference in the receptor type used between short and long glutamate exposures as activation of the N-methyl-D-asparate (NMDA) receptor was in both cases responsible for the motor neuron death. Cell death through activation of alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) receptors only became apparent when desensitization of these receptors was prevented. In such conditions, motor neurons became much more sensitive to excitotoxicity, and activation of different types of AMPA receptors mediated motor neuron death after short, compared to long, exposures to the non-desensitizing AMPA receptor agonist, KA. Short KA exposures selectively affected motor neurons containing Ca(2+)-permeable AMPA receptors, as the KA effect was completely inhibited by Joro spider toxin and only motor neurons that were positive for the histochemical Co(2+) staining were killed. A long exposure to KA affected motor neurons through both Ca(2+)-permeable and Ca(2+)-impermeable AMPA receptors. The selective death of motor neurons vs. dorsal horn neurons was observed after short KA exposures indicating that the selective vulnerability of motor neurons to excitotoxicity is related to the presence of Ca(2+)-permeable AMPA receptors.     

GIRK2 expression in dopamine neurons of the substantia nigra and ventral tegmental area

G-protein-regulated inward-rectifier potassium channel 2 (GIRK2) is reported to be expressed only within certain dopamine neurons of the substantia nigra (SN), although very limited data are available in humans. We examined the localization of GIRK2 in the SN and adjacent ventral tegmental area (VTA) of humans and mice by using either neuromelanin pigment or immunolabeling with tyrosine hydroxylase (TH) or calbindin. GIRK2 immunoreactivity was found in nearly every human pigmented neuron or mouse TH-immunoreactive neuron in both the SN and VTA, although considerable variability in the intensity of GIRK2 staining was observed. The relative intensity of GIRK2 immunoreactivity in TH-immunoreactive neurons was determined; in both species nearly all SN TH-immunoreactive neurons had strong GIRK2 immunoreactivity compared with only 50-60% of VTA neurons. Most paranigral VTA neurons also contained calbindin immunoreactivity, and approximately 25% of these and nearby VTA neurons also had strong GIRK2 immunoreactivity. These data show that high amounts of GIRK2 protein are found in most SN neurons as well as in a proportion of nearby VTA neurons. The single previous human study may have been compromised by the fixation method used and the postmortem delay of their controls, whereas other studies suggesting that GIRK2 is located only in limited neuronal groups within the SN have erroneously included VTA regions as part of the SN. In particular, the dorsal layer of dopamine neurons directly underneath the red nucleus is considered a VTA region in humans but is commonly considered the dorsal tier of the SN in laboratory species.     

Interrelationship of the distribution of neuropeptides and tyrosine hydroxylase immunoreactivity in the human substantia Nigra

The relationship in the human substantia nigra of peptidergic fibers with intrinsic dopaminergic neurons was studied in adjacent coronal sections of the mesencephalon immunohistochemically stained for enkephalin (ENK), substance P (SP), and tyrosine (TH) hydroxylase immunoreactivity. TH-positive elements are present in the substantia nigra in at least two different arrangements: 1) a dorsal tier of rather loosely arranged neurons, which is continuous medially with the ventral tegmental area and laterally with the retrorubral area, 2) a ventral tier of more closely packed neurons, clusters of which frequently form finger-like extensions deep into the pars reticulata. This ventral region contains TH-positive dendrites extending ventrally into the pars reticulata. The distribution of ENK is mainly restricted to the medial half of the ventral aspect of the substantia nigra, while SP occupies its entire rostral-caudal and medial-lateral extents. Peptide-positive fibers vary in density from dense to light. There is very little overlap between the dorsal tier of the TH-positive neurons and the ENK or SP staining. The dorsal part of the peptide-immunoreactive area extensively overlaps with the TH-positive neurons of the ventral tier of cells. The ventral part of the peptide-positive area overlaps with the pars reticulata of the substantia nigra in which the TH-positive dendrites extend. The overlap between the neuropeptide fibers and the TH-positive cells of the ventral tier is not complete, with cells found both within and outside peptide-positive fiber networks. Three patterns of overlap emerge. In dorsal regions elongated cell clusters lie partially within and partially outside the dense peptide-positive fiber networks. In the ventral regions TH-positive cells are either completely embedded within peptide fibers or clusters of cells are present in peptide-free zones. These data suggest that specific peptidergic pathways differentially innervate the substantia nigra. TH cells which lie within or outside these fibers may reflect functionally different subsystems in the striatonigral pathways in the human.     

NMDA and non-NMDA receptor-mediated excitotoxicity are potentiated in cultured striatal neurons by prior chronic depolarization.

The excitatory input from cortex and/or thalamus to striatum appears to promote the maturation of glutamate receptors on striatal neurons, but the mechanisms by which it does so have been uncertain. To explore the possibility that the excitatory input to striatum might influence glutamate receptor maturation on striatal neurons, at least in part, by its depolarizing effect on striatal neurons, we examined the influence of chronic KCl depolarization on the development of glutamate receptor-mediated excitotoxic vulnerability and glutamate receptors in cultured striatal neurons. Dissociated striatal neurons from E17 rat embryos were cultured for 2 weeks in Barrett's medium containing either low (3 mM) or high (25 mM) KCl. The vulnerability of these neurons to NMDA receptor agonists (NMDA and quinolinic acid), non-NMDA receptor agonists (AMPA and KA), and a metabotropic glutamate receptor agonist (trans-ACPD) was examined by monitoring cell loss 24 h after a 1-h agonist exposure. We found that high-KCl rearing potentiated the cell loss observed with 500 microM NMDA or 250 microM KA and yielded cell loss with 250 microM AMPA that was not evident under low KCl rearing. In contrast, neither QA up to 5 mM nor trans-ACPD had a significant toxic effect in either KCl group. ELISA revealed that chronic high KCl doubled the abundance of NMDA NR2A/B, AMPA GluR2/3, and KA GluR5-7 receptor subunits on cultured striatal neurons and more than doubled AMPA GluR1 and GluR4 subunits, but had no effect on NMDA NR1 subunit levels. These receptor changes may contribute to the potentiation of NMDA and non-NMDA receptor-mediated excitotoxicity shown by these neurons following chronic high-KCl rearing. Our studies suggest that membrane depolarization produced by corticostriatal and/or thalamostriatal innervation may be required for maturation of glutamate receptors on striatal neurons, and such maturation may be important for expression of NMDA and non-NMDA receptor-mediated excitotoxicity by striatal neurons. Striatal cultures raised under chronically depolarized conditions may, thus, provide a more appropriate culture model to study the role of NMDA or non-NMDA receptor subtypes in excitotoxicity in striatum.     

Excitotoxicity in the embryonic chick spinal cord.

Recent evidence implicates excitatory amino acids (EAAs), acting as excitotoxic agents, in the pathogenesis of neurological disorders involving the spinal cord. In this study, we used the chick embryo spinal cord as an in vitro model for studying the sensitivity of spinal neurons to the excitotoxic effects of EAA agonists. Compounds tested include the prototypic receptor-specific agonists, N-methyl-D-aspartate (NMDA), quisqualic acid (Quis), and kainic acid (KA), and the plant-derived excitotoxic food poisons, beta-N-oxalylamino-L-alanine, beta-N-methylamino-L-alanine, and domoic acid. Each agonist induced concentration-dependent acute degeneration of neurons distributed throughout the spinal cord. These cytopathological changes consisted of acute edematous degeneration of dendrosomal structures in the dorsal horn and intermediate zone, and dark cell changes with intracytoplasmic vacuolization of motor neurons; this damage is identical to that induced by excitotoxin agonists in other regions of the central nervous system. The NMDA receptor-specific antagonist MK-801 completely blocked toxicity of NMDA, and the nonNMDA antagonist CNQX preferentially blocked the toxicity of Quis- and KA-type agonists in the spinal cord. Our findings suggest that (1) the majority of spinal neurons have all three subtypes of EAA receptors, making them acutely vulnerable to excitotoxin exposure; and (2) EAA antagonists are effective in preventing excitotoxin-induced damage of the spinal cord.     

Age-related changes in dopamine transporters and accumulation of 3-nitrotyrosine in rhesus monkey midbrain dopamine neurons: relevance in selective neuronal vulnerability to degeneration

Aging is the strongest risk factor for developing Parkinson's disease (PD). There is a preferential loss of dopamine (DA) neurons in the ventral tier of the substantia nigra (vtSN) compared to the dorsal tier and ventral tegmental area (VTA) in PD. Examining age-related and region-specific differences in DA neurons represents a means of identifying factors potentially involved in vulnerability or resistance to degeneration. Nitrative stress is among the factors potentially underlying DA neuron degeneration. We studied the relationship between 3-nitrotyrosine (3NT; a marker of nitrative damage) and DA transporters [DA transporter (DAT) and vesicular monoamine transporter-2 (VMAT)] during aging in DA subregions of rhesus monkeys. The percentage of DA neurons containing 3NT increased significantly only in the vtSN with advancing age, and the vtSN had a greater percentage of 3NT-positive neurons when compared to the VTA. The relationship between 3NT and DA transporters was determined by measuring fluorescence intensity of 3NT, DAT and VMAT staining. 3NT intensity increased with advancing age in the vtSN. Increased DAT, VMAT and DAT/VMAT ratios were associated with increased 3NT in individual DA neurons. These results suggest nitrative damage accumulates in midbrain DA neurons with advancing age, an effect exacerbated in the vulnerable vtSN. The capacity of a DA neuron to accumulate more cytosolic DA, as inferred from DA transporter expression, is related to accumulation of nitrative damage. These findings are consistent with a role for aging-related accrual of nitrative damage in the selective vulnerability of vtSN neurons to degeneration in PD.     

Differential NMDA receptor-dependent calcium loading and mitochondrial dysfunction in CA1 vs. CA3 hippocampal neurons

Hippocampal CA1 pyramidal neurons are selectively vulnerable to ischemia, while adjacent CA3 neurons are relatively resistant. Although glutamate receptor-mediated mitochondrial Ca²⁺ overload and dysfunction is a major component of ischemia-induced neuronal death, no direct relationship between selective neuronal vulnerability and mitochondrial dysfunction has been demonstrated in intact brain preparations. Here, we show that in organotypic slice cultures NMDA induces much larger Ca²⁺ elevations in vulnerable CA1 neurons than in resistant CA3. Consequently, CA1 mitochondria exhibit stronger calcium accumulation, more extensive swelling and damage, stronger depolarization of their membrane potential, and a significant increase in ROS generation. NMDA-induced Ca²⁺ and ROS elevations were abolished in Ca²⁺-free medium or by NMDAR antagonists, but not by zinc chelation. We conclude that Ca²⁺ overload-dependent mitochondrial dysfunction is a determining factor in the selective vulnerability of CA1 neurons.     

Kainic acid on neostriatal neurons intracellularly recorded in vitro: electrophysiological evidence for differential neuronal sensitivity

The electrophysiological effects produced by different concentrations of kainic acid (KA) were studied by utilizing intracellular recordings from neostriatal slices. In most of the recorded cells (81%), concentrations of KA ranging between 10 and 300 nM produced reversible and dose-dependent membrane depolarizations. Higher concentrations of this agonist caused larger depolarizations and changes of the membrane properties of the recorded neurons not reversible during the time of recording. In a smaller percentage (19%) of the recorded cells, 10-100 nM KA did not produce significant membrane depolarizations; in these neurons, the depolarizations produced by higher concentrations of KA were small and reversible. The 2 populations of neurons showed similar electrophysiological properties and did not reveal differential sensitivity to quisqualic acid (QUIS; 10-30 microM) or to NMDA (10-30 microM). Tetrodotoxin (TTX; 1 microM) did not reduce the depolarizations produced by KA and by NMDA. Low-calcium, cobalt-containing solutions abolished the effects produced by NMDA, but not the KA-induced depolarizations. Kynurenic acid (500 microM) significantly antagonized the depolarizations produced by KA and reduced the changes of the membrane properties caused by high doses of this agonist. In several neurons, KA induced bicuculline-sensitive synaptic depolarizing potentials. Our findings suggest the presence of 2 subpopulations of neostriatal neurons showing differential postsynaptic sensitivity to KA. The differential sensitivity of neostriatal neurons to KA might influence the responses of these cells to glutamatergic cortical inputs and the degenerative changes observed in neostriatal neurons in some pathological conditions.