Attenuation of malonate toxicity in primary mesencephalic cultures using the GABA transport blocker, NO-711.

Cultured rat mesencephalic neurons were used to assess the effects of gamma-aminobutyric acid (GABA) transport blockers on toxicity caused by malonate, a reversible, competitive inhibitor of succinate dehydrogenase. Previous studies utilizing an ex vivo chick retinal preparation have shown that GABA release and cell swelling are early consequences of acute energy impairment and that GABA transport blockers attenuate this toxicity. The present results demonstrate that the nonsubstrate GABA transport blocker, NO-711 (1 nM-1 microM), dose-dependently protected cultured mesencephalic dopamine (DA) and GABA neurons from malonate-induced toxicity. Similar protection was demonstrated with nipecotic acid (1 mM) and SKF89976A (100 nM), substrate and nonsubstrate GABA transport blockers, respectively. These compounds by themselves produced no signs of toxicity, although nipecotic acid caused a long-term decrease in GABA uptake not associated with toxicity. Compounds which decrease intracellular reactive oxygen species (ROS) are protective in this model, but NO-711 did not prevent the rise in intracellular ROS induced by malonate, indicating its protective effects were downstream of ROS production. Supplementation of malonate treated cultures with the GABA(A) agonist, muscimol (10 microM), increased the toxicity toward the DA and GABA neuron populations. Antagonists at the GABA(A) and glycine receptors provided partial protection to both the GABA and DA neurons. These findings suggest that the GABA transporter, GABA(A), and/or glycine channels contribute to cell damage associated with energy impairment in this model.

Lactate prevents the alterations in tissue amino acids, decline in ATP, and cell damage due to aglycemia in retina.

Under conditions of energy impairment, CNS tissue can utilize substrates other than glucose to maintain energy metabolism. Retinas produce large amounts of lactate, although it has not been shown that lactate can be utilized by retina to prevent the cell damage associated with hypoglycemia. To investigate this, intact, isolated retinas were subjected to aglycemic conditions in the presence or absence of 20 mM lactate. Retinas incubated in the absence of glucose for 60 min showed a threefold elevation in tissue aspartate and 60% decreases in tissue glutamate and glutamine, demonstrating a mobilization of carbon from glutamine and glutamate to the tricarboxylic acid cycle. Lactate prevented these changes in tissue amino acids, indicating metabolism of lactate with sparing of tissue glutamate and glutamine. Tissue ATP was 20 and 66% of control values with zero glucose or zero glucose plus lactate, respectively. Consistent with previous findings, incubation of retinas in the absence of glucose caused acute swelling of retinal neurons and release of GABA into the medium at 60 min. These acute toxic affects caused by the absence of glucose were completely prevented by the presence of lactate. At 24 h of recovery following 60 min of zero glucose, many pyknotic profiles were observed and lactate dehydrogenase (LDH) release into the medium was elevated sevenfold, indicating the extent of cell death. In contrast, no elevation in LDH was found and histology appeared normal in retinas exposed to zero glucose in the presence of lactate. alpha-Cyano-4-hydroxy cinnamate (4-CIN; 0.5 mM), an inhibitor of the monocarboxylic acid transporter and mitochondrial pyruvate carrier, blocked the ability of lactate to maintain ATP and protect retinas from aglycemia but had no effect on ATP or toxicity per se. Derangements in tissue aspartate, glutamate, and glutamine, which were prevented by lactate during zero glucose incubation, were again observed with lactate plus zero glucose in the presence of 4-CIN. However, 0.5 mM 4-CIN alone in the presence of glucose produced similar increases in aspartate and decreases in glutamate and glutamine as observed with zero glucose while having only modest inhibitory effects on [U-(14)C]lactate uptake, suggesting the mitochondrial pyruvate carrier as the main site of action. The above findings show that lactate is readily utilized by the chick retina during glucose deprivation to prevent derangements in tissue amino acids and ATP and retinal neuronal cell death.

Oxidative stress during energy impairment in mesencephalic cultures is not a downstream consequence of a secondary excitotoxicity.

Past studies have shown that inhibiting energy metabolism with malonate in mesencephalic cultures damages neurons by mechanisms involving N-methyl-D-aspartate receptors and free radicals. Overstimulation of N-methyl-D-aspartate receptors is known to produce free radicals. This study was, therefore, carried out to determine if N-methyl-D-aspartate receptor activation triggered by energy impairment was a significant contributor to the oxidative stress generated during energy inhibition. Exposure of mesencephalic cultures to malonate for the minimal time required to produce toxicity, i.e. 6h, resulted in an increase in the efflux of both oxidized and reduced glutathione, and a decrease in tissue levels of reduced glutathione. In contrast, exposure to 1mM glutamate for 1h caused an increased efflux of reduced glutathione, but no changes in intra- or extracellular oxidized glutathione or intracellular reduced glutathione. Blocking N-methyl-D-aspartate receptors with MK-801 (0.5 microM) during malonate exposure did not modify malonate-induced alterations in glutathione status or free radical generation as monitored by dihydrochlorofluorescein diacetate and dihydrorhodamine 123 fluorescence. In contrast, the increase in dihydrorhodamine fluorescence caused by glutamate was completely blocked by MK-801. Reduction of tissue glutathione with a 24h pretreatment with 10 microM buthionine sulfoxamine, as shown previously, greatly potentiated malonate-induced toxicity to dopamine and GABA neurons, but had no potentiating effect on toxicity due to glutamate. The findings indicate that although oxidative stress mediates damage due either to energy deprivation or excitotoxicity, N-methyl-D-aspartate receptor over-stimulation does not contribute significantly to the oxidative stress that is incurred during malonate exposure.

Origins of the extracellular glutamate released during total metabolic blockade in the immature retina.

Previous studies have shown that complete blockade of metabolism in embryonic chick retina causes a time-dependent increase in the release of glutamate into the extracellular space. The present study examined the cellular source of this glutamate, i.e., neuronal and/or glial. Pure cultures of retinal neurons or glia were labeled for 10 min at 37 degrees C with [3H]acetate. Retinal glia, but not retinal neurons, were found to selectively and preferentially metabolize acetate, thus producing 3H-labeled amino acids in the glial compartment. This finding provides direct evidence to substantiate findings from several other laboratories that have indirectly determined the preferential metabolism of acetate by glia by using mixed neuronal/glial populations. To study the cellular source of glutamate released during total metabolic blockade, whole retina were prelabeled with [3H]acetate plus [U-14C]glucose (to label the neuronal compartment). Total metabolic blockade was instituted with a combination of iodoacetate (IOA) plus KCN, and the release of glutamate into the medium was followed at 5, 15, and 30 min. During total energy blockade, net extracellular glutamate was not elevated at 5 min [0.17 +/- 0.02 vs. 0.12 +/- 0.01 microM for treated vs. control retina (means +/- SEM), respectively], but was increased significantly at 15 (1.2 +/- 0.26 microM) and 30 min (2.6 +/- 0.22 microM). Total [3H]glutamate in the medium during IOA/KCN treatment was unchanged at 5 min, but was increased 1.5- and threefold above basal levels at 15 and 30 min, respectively. During the time when extracellular glutamate increased, the specific activity of [3H]glutamate remained fairly constant, 731 +/- 134 and 517 +/- 82 dpm/nmol (means +/- SEM) at 15 and 30 min, respectively. In contrast, 14C-labeled glutamate in the medium did not increase during IOA/KCN treatment and paralleled basal levels. Thus, the specific activity of 14C-labeled extracellular glutamate decreased from 309 +/- 87 dpm/nmol at 15 min to 42 +/- 8 dpm/nmol at 30 min. Prior loading of the tissue with 0.5 mM trans-pyrrolidine-2,4-dicarboxylate (t-PDC), a glutamate transport inhibitor, blocked 57% of the glutamate released at 30 min of IOA/KCN exposure, suggesting that reversal of an Na+-dependent glutamate transporter was a key contributor to the appearance of extracellular glutamate during energy deprivation. The increase in extracellular [3H]glutamate, constancy of the specific activity of extracellular [3H]glutamate, decrease in the specific activity of extracellular [14C]glutamate, and attenuation of release by prior loading with t-PDC indicate that glial pools of glutamate released via reversal of the transporter contribute significantly to the rise in extracellular glutamate after metabolic inhibition in this preparation.

Excitotoxicity and oxidative stress during inhibition of energy metabolism.

Glutamate receptor involvement and oxidative stress have both been implicated in damage to neurons due to impairment of energy metabolism. Using two different neuronal in vitro model systems, an ex vivo chick retinal preparation and dopamine neurons in mesencephalic culture, the involvement and interaction of these events as early occurring contributors to irreversible neuronal damage have been examined. Consistent with previous reports, the early acute changes in the retinal preparation, as well as irreversible loss of dopamine neurons due to inhibition of metabolism, can be prevented by blocking NMDA receptors during the time of energy inhibition. Oxidative stress was suggested to be a downstream consequence and contributor to neuronal cell loss due to either glutamate receptor overstimulation or metabolic inhibition since trapping of free radicals with the cyclic nitrone spin-trapping agent MDL 102,832 (1 mM) attenuated acute excitotoxicity in the retinal preparation or loss of mesencephalic dopamine neurons due to either metabolic inhibition by the succinate dehydrogenase inhibitor, malonate, or exposure to excitotoxins. In mesencephalic culture, malonate caused an enhanced efflux of both oxidized and reduced glutathione into the medium, a significant reduction in total reduced glutathione and a significant increase in total oxidized glutathione at time points that preceded those necessary to cause toxicity. These findings provide direct evidence for early oxidative events occurring following malonate exposure and suggest that the glutathione system is important for protecting neurons during inhibition of energy metabolism. Consistent with this, lowering of glutathione by buthionine sulfoxamine (BSO) pretreatment greatly potentiated malonate toxicity in the mesencephalic dopamine population. In contrast, BSO pretreatment did not potentiate glutamate toxicity. This latter finding indicates dissimilarities in the type of oxidative stress that is generated by the two insults and suggests that the oxidative challenge during energy inhibition is not solely a downstream consequence of glutamate receptor overstimulation.

Role of oxidative stress and the glutathione system in loss of dopamine neurons due to impairment of energy metabolism.

Alterations in the glutathione system and impairment in energy metabolism have both been implicated in the loss of dopamine neurons in Parkinson's disease. This study examined the importance of cellular glutathione and the involvement of oxidative stress in the loss of mesencephalic dopamine and GABA neurons due to inhibition of energy metabolism with malonate, the reversible, competitive inhibitor of succinate dehydrogenase. Consistent with previous findings, exposure to malonate for 24 h followed by 48 h of recovery caused a dose-dependent loss of the dopamine population with little effect on the GABA population. Toxicity was assessed by simultaneous measurement of the high-affinity uptake of [3H]dopamine and [14C]GABA. Total glutathione content in rat mesencephalic cultures was decreased by 65% with a 24-h pretreatment with 10 microM buthionine sulfoxamine. This reduction in glutathione level greatly potentiated damage to both the dopamine and GABA populations and removed the differential susceptibility between the two populations in response to malonate. These findings point to a role for oxidative stress occurring during energy impairment by malonate. Consistent with this, several spin-trapping agents, alpha-phenyl-tert-butyl nitrone and two cyclic nitrones, MDL 101,002 and MDL 102,832, completely prevented malonate-induced damage to the dopamine neurons in the absence of buthionine sulfoxamine. The spin-trapping agents also completely prevented toxicity to both the dopamine and GABA populations when cultures were exposed to malonate after pretreatment with buthionine sulfoxamine to reduce glutathione levels. Counts of tyrosine hydroxylase-positive neurons verified enhancement of cell loss by buthionine sulfoxamine plus malonate and protection against cell loss by the spin-trapping agents. NMDA receptors have also been shown to play a role in malonate-induced dopamine cell loss and are associated with the generation of free radicals. Consistent with this, toxicity to the dopamine neurons due to a 1-h exposure to 50 microM glutamate was attenuated by the nitrone spin traps. These findings provide evidence for an oxidative challenge occurring during inhibition of energy metabolism by malonate and show that glutathione is an important neuroprotectant for midbrain neurons during situations when energy metabolism is impaired.

Contribution of glial metabolism to neuronal damage caused by partial inhibition of energy metabolism in retina.

Glial cells are relatively resistant to energy impairment, although little is known of the extent to which glial metabolism is affected during partial energy impairment and how this influences neurons. Fluorocitrate has been shown to be a glial specific metabolic inhibitor. Its selective effect on chick retinal Müller cells was verified by measuring incorporation of radiolabel from 3H-acetate and U-14C-glucose into glutamate and glutamine following exposure of isolated embryonic day 15-18 chick retina to 20 microm fluorocitrate. Fluorocitrate significantly reduced the incorporation of radiolabel from acetate and glucose into glutamine, with less effect on incorporation of label from acetate into glutamate and no reduction of label from glucose into glutamate. The relative specific activity (RSA; ratio of glutamine to glutamate) increased between embryonic day 15 and 18 consistent with the increase in glutamine synthetase activity that occurs in Müller cells at this time in chick retinal development. As with previous findings, mild energy stress produced by inhibiting glycolysis with the general inhibitor iodoacetate (IOA) for up to 45 min, caused acute neuronal damage that was predominately NMDA receptor mediated and occurred in the absence of a net efflux of excitatory amino acids. Acute NMDA-mediated toxicity in this preparation is characterized by the selective damage to amacrine and ganglion cells and quantitatively, by GABA release into the medium. When IOA was combined with fluorocitrate, acute toxicity was potentiated and temporally accelerated. Acute damage was first noted at 15 min, occurred throughout all retinal layers and was accompanied by an overflow of excitatory amino acids at 30 and 45 min. Blocking NMDA receptors with MK-801 during IOA plus fluorocitrate exposure attenuated the rise in excitatory amino acids and prevented the swelling in neuronal, but not Müller cells. Following incorporation of radiolabel from acetate and glucose into glutamate and glutamine after different times of exposure to IOA showed that while the effects of incorporation of label from glucose were immediate, glutamine synthesis from acetate was preserved for a longer period of time. These findings suggest that during a partial energy impairment, neuronal metabolism is affected to a greater extent than is glial metabolism. Glial cells may play a protective role in this situation, and can delay the onset of acute neuronal damage.

Energy stress-induced dopamine loss in glutathione peroxidase-overexpressing transgenic mice and in glutathione-depleted mesencephalic cultures.

The role of the glutathione system in protecting dopamine neurons from a mild impairment of energy metabolism imposed by the competitive succinate dehydrogenase inhibitor, malonate, was investigated in vitro and in vivo. Treatment of mesencephalic cultures with 10 microM buthionine sulfoxamine for 24 h reduced total glutathione levels in the cultures by 68%. Reduction of cellular glutathione per se was not toxic to the dopamine population, but potentiated toxicity when the cultures were exposed to malonate. In contrast, transgenic mice overexpressing glutathione peroxidase (hGPE) that received an intrastriatal infusion of malonate (3 mumol) into the left side had significantly less loss of striatal dopamine than their hGPE-negative littermates when assayed 1 week following infusion. These studies demonstrate that manipulation of the glutathione system influences susceptibility of dopamine neurons to damage due to energy impairment. The findings may provide insight into the loss of dopamine neurons in Parkinson's disease in which defects in both energy metabolism and the glutathione system have been identified.

Activity at the GABA transporter contributes to acute cellular swelling produced by metabolic impairment in retina.

The role of the GABA transporter in acute toxicity in chick retina due to metabolic inhibition was investigated by the use of several substrate (nipecotic acid, THPO) and nonsubstrate (SKF 89976A, NO711) GABA transport inhibitors. Metabolic stress-induced acute toxicity in the retina is characterized by swelling of distinct populations of retinal neurons and selective release of GABA into the medium. Inhibitor concentrations were based on that needed to attenuate 14C-GABA uptake at its approximate KM concentration by > or = 70%. Under basal conditions, substrate, but not nonsubstrate, inhibitors increased extracellular GABA, but did not cause histological swelling per se. Under conditions of glycolytic inhibition, nonsubstrate, but not substrate, inhibitors significantly attenuated acute toxicity. Metabolic stress-induced acute toxicity was not altered by the GABA agonist muscimol, nor did muscimol reverse the protective effects of nonsubstrate transport inhibitors, suggesting that an increase in extracellular GABA during metabolic stress was not a component of the acute phase of toxicity. The results indicate that during metabolic inhibition, activity at the GABA transporter contributes to acute cellular swelling.

Hypothermia and metabolic stress: narrowing the cellular site of early neuroprotection.

In a previous study we showed that hypothermia of 30 degrees C can expand the time during which retinal neurons in vitro can have their metabolism inhibited without adverse effects. In isolated chick retinae, the first signs of acute toxicity resulting from mild, partial, pharmacological inhibition of metabolism are N-methyl-D-aspartate (NMDA)-mediated histological swelling and gamma-aminobutyric acid release. More prolonged or severe inhibition of metabolism results in involvement of non-NMDA glutamate receptors and voltage-dependent Na+ channels. In this study we examine early cellular events that may be associated with hypothermic protection. The early cellular events thought to follow metabolic stress involve a decrease in ATP, reduced activity of the Na+, K(+)-ATPase, which renders ion leakage unopposed, degradation of the membrane potential and subsequent activation of ionotropic glutamate receptors and voltage-dependent Na+ channels, which leads to acute toxicity. Reduction by hypothermia of the rate of loss of ATP was shown, In past work, to only partially account for neuroprotection. In the present study, inhibition of the Na+, K(+)-ATPase with 10 microM ouabain for 30 min at 37 degrees C led to acute toxicity that was similar to the toxicity produced by severe metabolic stress, i.e., primarily excitotoxic and mediated by NMDA receptors and secondarily involving non-NMDA receptors and voltage-dependent Na+ channels. Swelling and increased gamma-aminobutyric acid release were first evident at 15 min of incubation with ouabain at 37 degrees C. Hypothermia (30 degrees C) delayed the onset of acute excitotoxicity caused by ouabain. This protection was independent of an involvement with ATP loss, because ouabain treatment did not reduce ATP levels. Protection against ouabain suggests that hypothermia can intervene at steps subsequent to decreased Na+, K(+)-ATPase activity. In contrast, reducing the temperature to 30 degrees C did not attenuate NMDA-mediated secondary excitotoxicity caused by lowering of the membrane potential with increasing extracellular K+ concentrations (32-55 mM). However, hypothermia of 30 degrees C was able to reduce the rate of ouabain-induced 86Rb efflux. The findings described above suggest that a critical site of action for hypothermic protection is at a step between decreased Na+, K(+)-ATPase activity and degraded membrane potential, specifically, slowing of the rate of ion leakage.

Attenuation of excitotoxic cell swelling and GABA release by the GABA transport inhibitor SKF 89976A.

Acute excitotoxicity in the chick retina is characterized by cellular swelling and the subsequent selective release of GABA. In order to understand the source of GABA release, embryonic day 15 retina were incubated with 1 mM glutamate for 30 min in the presence or absence of the GABA transport inhibitor SKF 89976A (1-100 microM). SKF 89976A dose-dependently attentuated glutamate-induced GABA release (IC50, 39 microM). Histological examination of retina showed that SKF 89976A greatly reduced cellular swelling caused by glutamate exposure. Interaction of SKF 89976A with glutamate receptors was ruled out as a possible reason for protection vs acute glutamate excitotoxicity, since SKF 89976A had no effect on glutamate receptor-induced 22Na+ influx. In contrast, the NMDA antagonist, MK-801, significantly blocked glutamate-evoked 22NA+ uptake. These studies indicate that reversal of the GABA transporter contributes to the bulk of GABA release during acute excitotoxicity in retina. Further, a net effect of the presence of SKF 89976A during glutamate exposure is reduction in cellular swelling. It is not clear at present if attenuation of swelling is mediated specifically by an interaction with the GABA transporter or by a nonspecific or indirect effect of SKF 89976A.

Relative vulnerability of dopamine and GABA neurons in mesencephalic culture to inhibition of succinate dehydrogenase by malonate and 3-nitropropionic acid and protection by NMDA receptor blockade.

The effects of different severities of metabolic stress on dopamine (DA) and gamma-aminobutyric acid (GABA) cell loss were examined in rat mesencephalic culture. Partial metabolic inhibition was induced in 12-day-old cultures by a 24-hr treatment with various concentrations of 3-nitropropionic acid(3-NPA, 0.1-0.5 mM) or malonate (10-50 mM), irreversible and reversible inhibitors of the Krebs cycle enzyme, succinate dehydrogenase. Cell damage to the DA and GABA populations was assessed after a 48-hr recovery period by simultaneous measurement of high affinity uptake for 3H-DA and 14C-GABA. 3-NPA or malonate caused a dose-dependent loss of DA uptake (EC50 0.21 or 42 mM, respectively). 3-NPA treatment was equally detrimental to the GABA population, whereas malonate exposure did not cause any significant loss of GABA uptake. The presence of the NMDA antagonist, MK-801 (1 microM), during 24 hr of 3-NPA or malonate treatment fully protected against DA and GABA loss with 50 mM malonate or 0.25 mM 3-NPA and partially protected versus 0.5 mM 3-NPA. To determine the degree of metabolic stress imposed by 3-NPA and malonate, 12-day-old cultures were treated with 0.5 mM 3-NPA or 50 mM malonate for 3 hr and the rate of lactate formation was measured. lactate was increased nearly 2-fold at 3 hr of treatment with 3-NPA, but was not significantly elevated above basal with malonate treatment. SDH activity was decreased by 48 or 58% after 3 hr of treatment with 0.25 and 0.5 mM 3-NPA, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Excitotoxicity at both NMDA and non-NMDA glutamate receptors is antagonized by aurintricarboxylic acid: evidence for differing mechanisms of action.

In this study, the endonuclease inhibitor aurintricarboxylic acid (ATA) was examined for its ability to attenuate both acute and delayed excitotoxicity mediated through NMDA and non-NMDA glutamate receptors. Ex vivo embryonic chick retina, a model system frequently used for studies of excitotoxicity, was exposed to either 100 microM NMDA or kainate (KA) +/- various concentrations of ATA for 60 min, then allowed to recover for 24 h. Lactate dehydrogenase release into the medium and histology were assessed as measures of delayed toxicity. ATA attenuated lactate dehydrogenase release due to NMDA or KA in a dose-dependent manner. Histology revealed that ATA decreased the number of pyknotic profiles in response to either glutamate agonist. The mechanism of ATA protection was addressed. ATA was found to block NMDA- but not KA-mediated 22Na+ influx and cyclic GMP formation. In membrane binding studies, ATA was relatively selective for displacement at the NMDA receptor. The IC50 values for displacement of [3H]CGS 19755, alpha-[3H]amino-3-hydroxy-5-methylisoxazole-4-propionic acid ([3H]AMPA), or [3H]KA were 29.9 +/- 1.3, 313 +/- 46, and > 1,000 microM +/- SEM, respectively. ATA also fully attenuated NMDA-induced and partially attenuated KA-induced acute excitotoxicity as monitored histologically by tissue swelling and by the increase in GABA in the medium. Temporal studies of ATA efficacy indicated that ATA needed to be present during NMDA exposure to afford protection but, versus KA, was equally effective if administered immediately after KA exposure. Questions regarding the cellular penetration of ATA were raised because incubation with 100 microM ATA for 60 min had no effect on lactate formation or [3H]leucine incorporation into trichloroacetic acid-precipitable material, even though, in cell-free systems, ATA is a potent inhibitor of phosphofructokinase activity and protein synthesis. These studies demonstrate that ATA can protect against excitotoxicity mediated through NMDA or non-NMDA glutamate receptors. The mechanism of protection versus NMDA is through interruption of NMDA receptor interactions. ATA has no direct effect at the KA receptor; thus, its mechanism of protection versus KA is distinct from that versus NMDA and is, at present, unknown.

L-dopa cytotoxicity to PC12 cells in culture is via its autoxidation.

The mechanism of cytotoxicity of L-DOPA was studied in the rat pheochromocytoma PC12 cell line. The cytotoxicity of L-DOPA to PC12 cells was time and concentration dependent. Carbidopa, which inhibited the conversion of L-DOPA to dopamine, did not protect against L-DOPA cytotoxicity in PC12 cells. Furthermore, clorgyline, a selective inhibitor of monoamine oxidase type A, and pargyline, an inhibitor of both monoamine oxidase types A and B, both did not have an effect on L-DOPA toxicity. These findings suggest that cytotoxicity was not due to dopamine formed from L-DOPA. Catalase or superoxide dismutase each partially protected against L-DOPA toxicity in PC12 cells. In combination, the effects were synergistic and provided almost total protection against cytotoxicity. 6-Cyano-7-nitroquinoxaline-2,3-dione, an antagonist of non-NMDA receptors, did not protect against L-DOPA toxicity. These data suggest that toxicity of L-DOPA is most likely due to the action of free radicals formed as a result of its autoxidation. Furthermore, these findings suggest that patients on long-term L-DOPA therapy are potentially at risk from the toxic intermediates formed as a result of its autoxidation.

NMDA receptor involvement in toxicity to dopamine neurons in vitro caused by the succinate dehydrogenase inhibitor 3-nitropropionic acid.

Exposure of mesencephalic dopamine neurons to an irreversible inhibitor of succinate dehydrogenase (SDH), 3-nitropropionic acid (3-NPA), for 24 h on day 12 in vitro, produced a dose-dependent loss of high-affinity dopamine uptake when measured 48 h following 3-NPA removal. ATP concentrations in the cultures were reduced by 57% after 3 h of treatment with the highest concentration of 3-NPA tested (500 microM). To determine whether glutamate receptors mediated the dopamine toxicity by 3-NPA, cultures were examined for their sensitivity to excitatory amino acid-induced toxicity. Mesencephalic cultures exposed to either 100 microM NMDA or kainate, on day 12 for 24 h, showed complete loss of dopamine uptake following 48 h of recovery. The NMDA and non-NMDA antagonists, MK-801 (1 microM) or 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 15 microM), completely prevented the effects of NMDA or kainate, respectively, when present at the time of toxin exposure. In cultures treated with 3-NPA, MK-801, but not CNQX, significantly attenuated the loss of dopamine uptake. Direct measurement of the effect of 3-NPA on SDH activity showed that 3-NPA dose-dependently inhibited SDH in vitro in a manner commensurate with the loss of dopamine uptake by 3-NPA. MK-801 had no effect on basal SDH activity or on 3-NPA inhibition of SDH. These data are consistent with the interpretation that metabolic inhibition in dopamine neurons can trigger a secondary excitotoxicity that is mediated by NMDA receptors.

Studies on the characterization of the inhibitory mechanism of 4'-alkylated 1-methyl-4-phenylpyridinium and phenylpyridine analogues in mitochondria and electron transport particles.

1-Methyl-4-phenylpyridinium (MPP+), the toxic agent in MPTP-induced dopaminergic neurotoxicity, is thought to act by inhibiting mitochondrial electron transport at complex I. This study examined this latter action further with a series of 4'-alkylated analogues of MPP+. These derivatives had IC50 values that ranged from 0.5 to 110 microM and from 1.6 to 3,300 microM in mitochondria and electron transport particles (ETPs), respectively. The IC50 values of corresponding 4'-alkylated phenylpyridine derivatives to inhibit NADH-linked oxidation ranged from 10 to 205 microM in mitochondria and from 1.7 to 142 microM in ETPs. The potencies of both classes of inhibitors directly correlated with their ability to partition between 1-octanol and water. In mitochondria, increased hydrophobicity resulted in greater inhibition of NADH dehydrogenase but a smaller dependence on the transmembrane electrochemical gradient for accumulation of the pyridiniums as evidenced by an approximately 600-fold, versus only a 36-fold, increase in the IC50 of MPP+ versus 4'-pentyl-MPP+, respectively, in the presence of uncoupler. In ETPs, the analogous increase in potencies of the more hydrophobic analogues was also consistent with an inhibitory mechanism that relied on differential partitioning into the lipid environment surrounding NADH dehydrogenase. However, the pyridinium charge must play a major role in explaining the inhibitory mechanism of the pyridiniums because their potencies are much greater than would be predicted based solely on hydrophobicity. For example, in ETPs, 4'-decyl-MPP+ was nearly 80-fold more potent than phenylpyridine although the latter compound partitions twice as much into 1-octanol.(ABSTRACT TRUNCATED AT 250 WORDS)

Nitric oxide in retina: relation to excitatory amino acids and excitotoxicity.

This study was undertaken to determine whether nitric oxide pathways exist in the retina and are linked to excitatory amino acid (EAA)-induced increases in cyclic guanosine monophosphate (cGMP). Exposure of embryonic day 15 chick retina for 5 min to either 1 mM glutamate, 100 microM NMDA or 100 microM kainate (KA) increased cGMP content 2-3-fold. The putative environmental neurotoxins, domoic acid (DO, 20 microM), and beta-oxalyl-amino-L-alanine (BOAA, 200 microM), but not beta-methyl-amino-L-alanine (BMAA, 3 mM), also increased cGMP. The nitric oxide synthase inhibitor N-nitro-L-arginine (NNA) and nitric oxide scavenger, hemoglobin, completely blocked the increases in cGMP induced by the above glutamate-agonists. These glutamate agonist induced increases in cGMP were receptor mediated. MK-801, a NMDA receptor antagonist, blocked NMDA, and partially blocked glutamate-stimulated, cGMP formation. CNQX, a KA/AMPA receptor antagonist blocked cGMP increases produced by KA, BOAA and partially blocked those evoked by DO and glutamate. In order to examine the involvement of nitric oxide pathways in NMDA-mediated toxicity, the ability of NNA to protect against delayed excitotoxic damage caused by a 60 min exposure to NMDA was assessed. Delayed cell death, determined by LDH release and histology, following a 24 hr recovery period after NMDA treatment, was unchanged by the presence of NNA. NNA did not interfere with acute NMDA-stimulated GABA release indicating that NNA did not effect NMDA receptor interactions.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of the inhibitory mechanism of 1-methyl-4-phenylpyridinium and 4-phenylpyridine analogs in inner membrane preparations.

We have investigated the mechanism of the inhibition of membrane-bound NADH dehydrogenase by 1-methyl-4-phenylpyridinium (MPP+) and a series of its 4'-alkyl-substituted analogs of increasing hydrophobicity, as well as their neutral, desmethyl congeners. Comparison of hydrophobicity, as measured by partition coefficients, with the IC50 for the inhibition of NADH oxidase activity in mitochondrial inner membrane preparations shows a negative correlation, but the cationic inhibitors are more effective than the neutral analogs with similar hydrophobicity. The presence of 10 microM tetraphenylboron (TPB-) potentiates the inhibitory power of positively charged analogs up to 4'-pentyl-MPP+, while the neutral inhibitors are unaffected by TPB-. Without TPB-, the more hydrophilic analogs give incomplete inhibition, but the inclusion of TPB- permits the attainment of complete inhibition, accompanied by the appearance of sigmoidal titration curves. These data support the hypothesis that MPP+ analogs, like rotenone, are bound at two sites on the enzyme and occupancy of both is required for complete inhibition. TPB-, by forming ion pairs with the cationic analogs, facilitates their equilibration to both sites in membrane preparations. When present in molar excess over the MPP+ analog, TPB- partially reverses the inhibition by decreasing its concentration in the more hydrophilic binding site. The effect of temperature and of pH on the IC50 values for inhibition support the concept of dual binding sites, and the pH dependence of the inhibition reveals the participation of two ionized protein groups in the binding, one of which may be a thiol group.

Hypothermia, metabolic stress, and NMDA-mediated excitotoxicity.

Isolated embryonic retinas were metabolically stressed by inhibition of glycolysis either with iodoacetate (IOA) or by glucose withdrawal plus 10 mM 2-deoxy-D-glucose, and the effects of hypothermia were examined. Incubation at 30 versus 37 degrees C during 30 min of hypoglycemia with IOA completely reduced the rapid swelling-related GABA release [6 +/- 2 vs. 68 +/- 10 nmol/100 mg of protein (mean +/- SEM) for 30 and 37 degrees C, respectively]. Histology of the retina immediately following 30 min of metabolic stress at 30 degrees C appeared normal, whereas that at 37 degrees C showed a pattern of acute edema, characteristic of NMDA-mediated acute excitotoxicity. Coincubation with a competitive or noncompetitive NMDA antagonist, respectively, CGS-19755 (10 microM) or MK-801 (1 microM), during 30 min of hypoglycemia at 37 degrees C completely prevented tissue swelling, whereas extracellular GABA content remained at basal levels, indicating that the cytotoxic effects of IOA treatment for 30 min at 37 degrees C were NMDA receptor mediated. Longer periods of hypoglycemia at 37 degrees C produced acute toxicity that was only partially NMDA receptor mediated. Hypothermia delayed the onset of NMDA-mediated toxicity by 30-60 min. At 30 degrees C, the rate of loss of ATP was slowed during the first several minutes of hypoglycemia (82 and 58% of maximal tissue levels at 30 and 37 degrees C, respectively, at 5 min, but by 10 min, ATP levels were comparably reduced. After a transient exposure of retina to 50 microM NMDA in Mg(2+)-free medium, hypothermia significantly attenuated acute GABA release by 30%.(ABSTRACT TRUNCATED AT 250 WORDS)