Glutamate-induced cellular injury in isolated chick embryo retina: Müller cell localization of initial effects

Neurosteroids are endogenous neuroprotectants in an ex vivo glaucoma model

PURPOSE

Allopregnanolone is a neurosteroid and powerful modulator of neuronal excitability. The neuroprotective effects of allopregnanolone involve potentiation of γ-aminobutyric acid (GABA) inhibitory responses. Although glutamate excitotoxicity contributes to ganglion cell death in glaucoma, the role of GABA in glaucoma remains uncertain. The aim of this study was to determine whether allopregnanolone synthesis is induced by high pressure in the retina and whether allopregnanolone modulates pressure-mediated toxicity.

METHODS

Ex vivo rat retinas were exposed to hydrostatic pressure (10, 35, and 75 mm Hg) for 24 hours. Endogenous allopregnanolone production was determined by liquid chromatography and tandem mass spectrometry (LC-MS/MS) and immunochemistry. We also examined the effects of allopregnanolone, finasteride, and dutasteride (inhibitors of 5α-reductase), picrotoxin (a GABA(A) receptor antagonist), and D-2-amino-5-phosphonovalerate (APV, a broad-spectrum N-methyl-D-aspartate receptor [NMDAR] antagonist).

RESULTS

Pressure loading at 75 mm Hg significantly increased allopregnanolone levels as measured by LC-MS/MS. Elevated hydrostatic pressure also increased neurosteroid immunofluorescence, especially in the ganglion cell layer and inner nuclear layers. Staining was negligible at lower pressures. Enhanced allopregnanolone levels and immunostaining were substantially blocked by finasteride, but more effectively inhibited by dutasteride and APV. Administration of exogenous allopregnanolone suppressed pressure-induced axonal swelling in a concentration-dependent manner, while picrotoxin overcame these neuroprotective effects.

CONCLUSIONS

These results indicate that the synthesis of allopregnanolone is enhanced mainly via NMDARs in the pressure-loaded retina, and that allopregnanolone diminishes pressure-mediated retinal degeneration via GABAA receptors. Allopregnanolone and other related neurosteroids may serve as potential novel therapeutic targets for the prevention of pressure-induced retinal damage in glaucoma.

Abnormalities in glutamate metabolism and excitotoxicity in the retinal diseases

In the physiological condition, glutamate acts as an excitatory neurotransmitter in the retina. However, excessive glutamate can be toxic to retinal neurons by overstimulation of the glutamate receptors. Glutamate excess is primarily attributed to perturbation in the homeostasis of the glutamate metabolism. Major pathway of glutamate metabolism consists of glutamate uptake by glutamate transporters followed by enzymatic conversion of glutamate to nontoxic glutamine by glutamine synthetase. Glutamate metabolism requires energy supply, and the energy loss inhibits the functions of both glutamate transporters and glutamine synthetase. In this review, we describe the present knowledge concerning the retinal glutamate metabolism under the physiological and pathological conditions.

Effects of acutely elevated hydrostatic pressure in a rat ex vivo retinal preparation

PURPOSE

A new experimental glaucoma model was developed by using an ex vivo rat retinal preparation to examine the effects of elevated hydrostatic pressure on retinal morphology and glutamine synthetase (GS) activity.

METHODS

Ex vivo rat retinas were exposed to elevated hydrostatic pressure for 24 hours in the presence of glutamate or glutamate receptor antagonists and examined histologically. GS activity was assessed by colorimetric assay.

RESULTS

Pressure elevation induced axonal swelling in the nerve fiber layer. Axonal swelling was prevented by a combination of non-N-methyl-d-aspartate (non-NMDA) receptor antagonist and an NMDA receptor antagonist, indicating that the damage results from activation of both types of glutamate receptor. When glial function was preserved, the typical changes induced by glutamate consisted of reversible Müller cell swelling resulting from excessive glial glutamate uptake. The irreversible Müller cell swelling in hyperbaric conditions may indicate that pressure disrupts glutamate metabolism. Indeed, elevated pressure inhibited GS activity. In addition, glutamate exposure after termination of pressure exposure exhibited apparent Müller cell swelling.

CONCLUSIONS

These results suggest that the neural degeneration observed during pressure elevation is caused by impaired glial glutamate metabolism after uptake.

High extracellular glutamate modulates expression of glutamate transporters and glutamine synthetase in cultured astrocytes

Astroglial cells clear extracellular glutamate through the glutamate transporters, GLT-1 and GLAST, and subsequently convert the incorporated glutamate into glutamine by the enzyme, glutamine synthetase (GS). Several forms of acute brain injury are associated with the increased expression of GS and the decreased expression of GLT-1 and/or GLAST, eventually leading to the accumulation of excitotoxic extracellular glutamate concentrations. Although of clinical interest, the actual trigger of these injury-related changes of glial glutamate turnover remains unknown. Our present studies provide evidence that increases in extracellular glutamate, as present in many brain injuries, are sufficient to modulate the expression of glutamate transporters and GS. Subjecting cultured cortical astrocytes to glutamate concentrations of 0.5-20 mM resulted in a 25% loss of GLT-1 and GLAST protein levels after 24 h; GLT-1 and GLAST levels maximally decreased by 40% and 75%, respectively, after 72 h. This decline was not due to astroglial cell death, since glutamate up to 50 mM did not affect the survival of cultured astrocytes within 72 h. Major astrocytic cell death, however, occurred in cultures maintained under severe (4% O(2)), but not mild (9% O(2)), hypoxia, as well as in the presence of aspartate (>or=20 mM). Glutamate at >or=1 mM induced a prolonged increase of GS expression in contrast to glutamate transporters. Neither the decline of glutamate transporter expression nor the increase in GS expression induced by high extracellular glutamate was further modulated by mild hypoxia. Whereas the stimulatory influences of glutamate on GS expression were prevented by the non-competitive NMDA receptor antagonist, MK801, the inhibitory influences on glutamate transporter expression were neither sensitive to MK801, the non-competitive mGluR5 antagonist, MTEP, nor the non-competitive AMPA receptor antagonist, GYKI52466, implying that glutamate controls glial glutamate transport by a glutamate receptor-independent mechanism.

alpha-Aminoadipate induces progenitor cell properties of Müller glia in adult mice

PURPOSE

Retinal Müller glia in higher vertebrates have been reported to possess progenitor cell properties and the ability to generate new neurons after injury. This study was conducted to determine the signals that can activate this dormant capacity of Müller glia in adult mice, by studying their behavior during glutamate stimulation.

METHODS

Various concentrations of glutamate and its analogue alpha-aminoadipate, which specifically binds Müller glia, were injected subretinally in adult mice. Proliferating retinal cells were labeled by subretinal injection of 5'-bromo-2'-deoxyuridine (BrdU) followed by immunohistochemistry. Müller cell fates were analyzed in retinal sections by using double immunolabeling with primary antibodies against Müller and other retina-specific cell markers. The effects of glutamate and alpha-aminoadipate were also determined in purified Müller cell cultures.

RESULTS

Although high levels of glutamate induce retinal damage, subtoxic levels of glutamate directly stimulate Müller glia to re-enter the cell cycle and induce neurogenesis in vivo and in purified Müller cell cultures. alpha-Aminoadipate, which selectively target glial cells, also induced expression of progenitor cell markers by Müller cells in vitro or stimulated Müller cell migration to the outer nuclear layer (ONL) and to differentiate into photoreceptors in vivo.

CONCLUSIONS

Mature Müller glia in adult mice can be induced to dedifferentiate, migrate, and generate new retinal neurons and photoreceptor cells by alpha-aminoadipate or glutamate signaling. The results of this study suggest a novel potential strategy for treating retinal neurodegeneration, including retinitis pigmentosa and age-related macular degeneration, without transplanting exogenous cells.

Role of ammonia in reversal of glutamate-mediated Müller cell swelling in the rat retina

Glutamate is thought to participate in a variety of retinal degenerative disorders. However, when exposed to glutamate at concentrations up to 1 mM, ex vivo rat retinas typically exhibit Müller cell swelling, but not excitotoxic neuronal damage. This Müller cell swelling is reversible following glutamate washout, indicating that the glial edema is not required for glutamate-induced neuronal injury. It is unclear whether glutamate directly induces the Müller cell swelling or whether a metabolite of glutamate such as glutamine acts as an osmolyte to generate the cellular edema. To examine this issue, ex vivo rat retinas were exposed to 1 mM glutamate or 1 mM glutamine and were evaluated histologically. Glutamate was also combined with 1 mM ammonia or with methionine sulfoximine (MSO), an inhibitor of glutamine synthetase, the enzyme that catalyzes the synthesis of glutamine from glutamate and ammonia. Glutamate-mediated Müller cell swelling was blocked by co-administration of ammonia and the reversibility of Müller cell swelling was inhibited by MSO administered following glutamate exposure. Glutamine alone failed to induce Müller cell swelling. These results indicate that glutamate-mediated Müller cell swelling is unlikely to result from glutamine accumulation. Rather, conversion of glutamate to glutamine in a reaction involving ammonia helps reverse Müller cell swelling following exposure to exogenous glutamate.

A non-mitochondrial carboxylase, related to glutamate action is synthesized in the retina of the chick embryo

SDS-polyacrylamide gel electrophoresis (SDS-PAGE) and Western blot of chick retinal proteins at 21 days after intravitreal injection with 5 or 10 microM/eye Glu showed decreases in 37, 42, 53 and 57 kDa proteins and increases in 35, 72 and >94 kDa proteins. These proteins were carboxylases except for the 35 and 37 kDa proteins. With > or =15 microM/eye Glu, non-specific loss of retinal proteins was observed. In embryonic retinas, the 42 kDa protein was seen a few days before hatching, with biotin incorporation on days 3-6 after hatching. Immunohistochemistry indicated that this protein was a component of both the inner nuclear layer and the photoreceptor. Immunocytochemistry located it to the cell surface.

Glutamate transporters and retinal excitotoxicity

Glutamate appears to play a major role in several degenerative retinal disorders. However, exogenous glutamate is only weakly toxic to the retina when glutamate transporters on Müller glial cells are operational. In an ex vivo rat retinal preparation, we previously found that exogenous glutamate causes Müller cell swelling but does not trigger excitotoxic neurodegeneration unless very high concentrations that overwhelm the capacity of glutamate transporters are administered. To determine the role of glutamate transporters in Müller cell swelling and glutamate-mediated retinal degeneration, we examined the effects of DL-threo-beta-benzyloxyaspartate (TBOA), an agent that blocks glutamate transport but that unlike most available transport inhibitors is neither a substrate for transport nor a glutamate receptor agonist. We found that TBOA triggered severe retinal neurodegeneration attenuated by ionotropic glutamate receptor antagonists. TBOA-induced neuronal damage was also diminished by riluzole, an agent that inhibits endogenous glutamate release. In the presence of riluzole, to inhibit glutamate release plus TBOA to block glutamate uptake, the addition of low concentrations of exogenous glutamate triggered severe excitotoxic neuronal damage without inducing Müller cell swelling. We conclude that TBOA-sensitive glutamate transporters play an important role in regulating the neurodegenerative effects of glutamate in the rat retina.

Characterization of the human gene encoding alpha-aminoadipate aminotransferase (AADAT)

In mammals, the conversion of alpha-aminoadipate to alpha-ketoadipate by alpha-aminoadipate aminotransferase (AADAT) is an intermediate step in lysine degradation. A gene encoding for alpha-aminoadipate aminotransferase and kynurenine aminotransferase activities had been previously identified in the rat (KAT/AadAT). We identified the human gene (AADAT) encoding for AADAT. It has a 2329 bp cDNA, a 1278 bp open-reading frame, and is predicted to encode 425 amino acids with a mitochondrial cleavage signal and a pyridoxal-phosphate binding site. AADAT is 73% and 72% identical to the mouse and rat orthologs, respectively. The genomic structure spans 30 kb and consists of 13 exons. FISH studies localized the gene to 4q32.2. Two transcripts (approximately 2.9 and approximately 4.7 kb) were identified, with expression highest in liver. Bacterial expression studies confirm that the gene encodes for AADAT activity. The availability of the DNA sequence and enzyme assay will allow further evaluation of individuals suspected to have defects in this enzyme.

The intact isolated (ex vivo) retina as a model system for the study of excitotoxicity

Excitotoxicity is defined as a mode of neural cell death triggered by overactivation of receptors for the amino acid transmitter glutamate. There is considerable evidence that excitotoxicity is responsible for cell death in several neuropathological states, including some retinal diseases. The isolated retina, particularly from chick embryos, has been used extensively as an experimental system to characterize this process. This paper summarizes the use of isolated retina as a model system for studies of excitotoxicity from a theoretical and methodological point of view, and reviews results obtained from studies utilizing this system.

Swelling of Müller cells induced by AP3 and glutamate transport substrates in rat retina

Previous studies have shown that a single systemic injection of 2-amino-3-phosphonopropionate (AP3), an agonist/antagonist at metabotropic glutamate receptors, produces marked swelling of rodent Müller cells. To investigate the effects of AP3 on Müller cells, we used in vitro retinal segments prepared from 30 day old rats. Incubation with AP3 for 1 h or more caused severe swelling of Müller cells with the appearance of mitotic cellular profiles in the outer nuclear layer. The Müller cell swelling was mimicked by substrates for glutamate transporters, suggesting that AP3 may produce its effects via transport into glial cells. To determine whether AP3 is a substrate for glutamate transporters, we studied cultured rat hippocampal astrocytes using whole-cell patch clamp recordings. In hippocampal astrocytes, AP3 activated currents via an Na(+)-dependent glutamate transporter. Consistent with this, substitution of extracellular sodium with choline blocked Müller cell swelling in the rat retina. These results indicate that the acute glial swelling produced by AP3 results primarily from a fluid shift that accompanies the transport of AP3 and sodium into Müller cells.

Effects of Müller cell disruption on mouse photoreceptor cell development

Müller cells have been proposed to play an important role in photoreceptor cell development during the final stages of retinal maturation. The effect of disrupting Müller cells during mouse retinal development was investigated using the specific glial cell toxin, DL-alpha-aminoadipic acid (AAA). By giving multiple systemic injections over several days, impairment of Müller cell function was maintained during the period of photoreceptor migration and differentiation. Following three consecutive days of AAA treatment [commencing on post-natal (P) day 3, 5, 7 or 9, and examined at P8-P14], clumps of photoreceptor nuclei were displaced through the inner segments, lying immediately beneath the retinal pigment epithelium (RPE). Apart from the scalloped appearance of the outer retina, the overall lamination pattern of the retina was relatively well preserved. Even when AAA treatment commenced as early as P3, several days prior to the formation of the outer nuclear layer, the majority of photoreceptors migrated to their correct position and formed inner and outer segments. Therefore, the signals for photoreceptor migration are either provided by the Müller cells prior to P3, or, alternatively, are derived from different intrinsic or extrinsic cues. Disruption of Müller cell function was evidenced by decreased glutamine synthetase activity as well as by increased glial fibrillary acidic protein (GFAP) and decreased cellular retinaldehyde-binding protein (CRALBP) immunoreactivity. Immunocytochemistry with an antibody to CD44, which labels the microvilli of Müller cells at the outer limiting membrane, coupled with electron microscopic analysis, demonstrated that the zonulae adherentes between Müller cells and photoreceptors were either irregular or absent in areas adjacent to displaced clumps of photoreceptors. Thus AAA treatment of early post-natal mice results in localized disruption of the contacts between Müller cells and photoreceptors. These pathologic changes persist into adulthood since at P28, while short stretches of photoreceptors appeared relatively normal with fully developed outer segments, periodic clumps of displaced photoreceptor nuclei were still present adjacent to the RPE. In conclusion, Müller cell processes at the outer limiting membrane appear to play a critical role in providing a barrier to aberrant photoreceptor migration into the subretinal space.

Cystine/glutamate antiporter expression in retinal Müller glial cells: implications for DL-alpha-aminoadipate toxicity

A cytotoxicity of glutamate or related amino acids (10 mM) mediated by a cystine/glutamate antiporter (system Xc) has recently been demonstrated in N18 neuroblastoma-rat retina hybrid (N18RE105) cells and C6 glioma cells. The antiporter usually transports glutamate outside and cystine inside, thereby maintaining cellular concentrations of glutathione. High concentrations of glutamate inhibit cystine uptake and lead to depletion of cellular levels of glutathione. Among related amino acids, DL-alpha-aminoadipic acid (DL-alpha-AAA), which is well known as a selective gliotoxin in the retina, is also toxic to these cells. However, this does not explain why DL-alpha-AAA acts gliospecifically on the retina. To answer this question we first examined the effects of DL-alpha-AAA on the [35S]cystine uptake with parental N18 neuroblastoma cells and rat retina of the hybrid cells. DL-alpha-AAA showed a competitive inhibition of [35S]cystine uptake in the rat retina but not in the N18 cells. Such a competitive inhibition of cystine uptake by DL-alpha-AAA could also be seen in the carp retina. The cystine uptake with carp retina was mainly Na(+)-independent and Cl(-)-dependent as already described as a characteristic ion dependency of the Xc antiporter. We next examined the effects of exogenous cystine on the glutamate release from the retina. Cystine (1 mM) actually induced a glutamate release approximately twice that of the control. Furthermore, the glutamate release induced by cystine was also Na(+)-independent and Cl(-)-dependent, and was blocked by DL-alpha-AAA. An autoradiogram of [35S]cystine uptake in the carp retina showed typical radial glial Müller cells. A large incorporation of [35S]cystine into retinal glutathione fraction was detected by a high pressure liquid chromatography method during a 1-4-h incubation. A significant or large decrease of retinal levels of glutathione was observed one day ater an intravitreal injection of 8 mumol DL-alpha-AAA or L-alpha-AAA, respectively. Buthionine sulfoximine (2.5 mumol), a specific inhibitor of glutathione synthesis, induced a large decrease of retinal levels of glutathione and a loss of electroretinographic b-wave 20-30 h after treatment. Taken together, our present data with rat and carp retinas strongly indicate that the expression of cystine/glutamate antiporter is enriched in the retina, particularly in the glial Müller cells which have a rapid turnover pool for glutathione. The gliotoxin DL-alpha-AAA inhibits cystine uptake through this antiporter on the glial cells and elicits reduction of cellular levels of glutathione.(ABSTRACT TRUNCATED AT 400 WORDS)

Electrophysiological properties of neurones following mild and acute retinal ischaemia

Early electrophysiological changes following acute retinal ischaemia were studied by recording single or multiunit retinal ganglion cells and the electroretinogram (ERG) in barbiturate anaesthetized cats. Retinal ischaemia was initiated photochemically by platelet aggregation in retinal vessels which had been irradiated with monochromatic green light following an intravenous injection of Rose Bengal dye. No physiologically active ganglion cells were found within, or close to, the irradiated sites with chorioretinal oedema. On the other hand, in the areas 5-20 degrees away from the irradiation sites, ganglion cells had abnormally raised spontaneous (background) firing which obscured visually driven firing. The retinal areas where no physiologically active ganglion cells were found showed histopathological changes which are similar to those described for glutamate-induced retinal damage. Retinal areas where depolarized retinal ganglion cells were located, however, showed only minor vacuolation of the ganglion cell fibre layer. Early global electrophysiological changes following photochemically induced retinal vascular lesion were consistent with those predicted from the findings in the single cell study. Vascular lesions produced with high irradiation energy (10-30 J), which promote extensive chorioretinal oedema, resulted in gradual loss of visually responsive ganglion cells. Lesions produced by low-energy irradiation (2 J), causing slight narrowing of the blood columns in the vessels, on the other hand, resulted in significant increases in the amplitude and the implicit time of the ERG b-wave and the background firing of multiunit retinal ganglion cells. Electrophysiological changes associated with mild retinal ischaemia are analogous to physiological effects associated with exogenous glutamate or blockade of glutamate uptake.(ABSTRACT TRUNCATED AT 250 WORDS)

A mechanism for glutamate toxicity in the C6 glioma cells involving inhibition of cystine uptake leading to glutathione depletion

We have demonstrated that addition of L-glutamate in millimolar amounts to a culture of C6 glioma cells induced cell death within 24 h. The glutamate-induced toxicity in the C6 glioma cells was completely suppressed by adding L-cystine (0.4-1.0 mM), while the C6 cells degenerated in L-cystine-deprived culture medium. Kinetic studies of [35S]cystine and [3H]glutamate uptake showed that cystine competitively inhibited glutamate uptake, and conversely glutamate inhibited cystine uptake competitively, suggesting that C6 cells have a cystine/glutamate antiporter (system CG or Xc) similar to that already described in the periphery. Exogenous cystine (1 mM) stimulated a release of endogenous glutamate from C6 cells in a Na(+)-independent Cl(-)-dependent fashion. Thus, the antiporter normally transports glutamate out of and cystine into the cells. With the glutamate analogues tested, there was a good correlation between cytotoxicity and inhibition of cystine uptake. The de novo synthesis of glutathione was largely dependent upon the uptake of extracellular cystine. Intracellular levels of glutathione were dramatically decreased within 8-10 h by culture in glutamate-added or cystine-free medium. Vitamin E (100 microM), an antioxidant, rescued the death of C6 cells induced by glutamate exposure or by culture in cystine-deprived medium, but did not restore the apparent decrease of intracellular glutathione. Taken together, the present data strongly indicate that glutamate-induced cell death is initially due to inhibition of cystine uptake through the antiporter Xc system; such inhibition leads to glutathione depletion exposing the cells to oxidative stress. Excess of extracellular glutamate introduced from endogenous or exogenous roots might disorder this mechanism, resulting in cell death.

Mitogenic effects of excitatory amino acids in the adult rat retina

We studied the retinas of adult rats after the intravitreal injection of excitatory amino acids and ouabain. Kainic acid, domoic acid, N-methyl D-asparate and ouabain produced swelling and vacuolization of the outer plexiform, inner nuclear and inner plexiform layers and pyknosis. Mitoses were present in retinas treated with all agents other than N-methyl D-asparate. Rompun ketamine anesthesia blocked the mitogenic effects. Immunohistochemical labeling of both glial fibrillary acidic protein and S100 protein would indicate that the mitoses are occurring in glial cells. We suggest that the mitogenic effects are mediated through action on glial cationic channels, and might account for the reactive gliosis observed in some retinal lesions.

Action of the anti-ischemic agent ifenprodil on N-methyl-D-aspartate and kainate-mediated excitotoxicity

The efficacy of ifenprodil to antagonize N-methyl-D-aspartate (NMDA) and kainate (KA)-induced acute excitotoxicity was evaluated in embryonic day 13 chick retina. Incubation with either 50 microM NMDA or KA produced a characteristic histological lesion and release of endogenous gamma-aminobutyric acid (GABA). Ifenprodil potently attenuated NMDA-induced GABA efflux by 80% (IC50, 1.26 microM). Histology showed protection of all but a subpopulation of amacrine neurons and processes even at 500 microM ifenprodil. MK-801 and CGS 19755, uncompetitive and competitive NMDA antagonists, respectively, protected all NMDA-sensitive amacrines, including the ifenprodil-resistant population, whilst CNQX, a non-NMDA glutamate receptor antagonist, was ineffective. Ifenprodil was less effective versus KA, requiring 10-100-fold higher concentrations to significantly attenuate GABA release. The potent antagonism of NMDA-mediated acute excitotoxicity by ifenprodil may explain its efficacy as an anti-ischemic agent. Ifenprodil does, however, leave unprotected a subpopulation of NMDA-susceptible neurons suggesting a heterogeneity in the NMDA receptor population.

Excitatory amino acid-induced toxicity in chick retina: amino acid release, histology, and effects of chloride channel blockers

Acute excitotoxicity in embryonic chick retina and the ability of Cl- channel blockers to prevent toxicity were evaluated by measurement of endogenous amino acid release and histology. Treatment of retina with kainate, quisqualate, or N-methyl-D-aspartate resulted in a large dose-dependent release of gamma-aminobutyric acid and taurine, moderate release of glutamine and alanine, and no measurable release of glutamate or aspartate. Concentrations inducing maximal gamma-aminobutyric acid release were 50 microM quisquaalate, 100 microM kainate, and 100 microM N-methyl-D-aspartate. Treatment with 1 mM glutamate resulted in significant gamma-aminobutyric acid release, as well as an elevation in medium aspartate levels. Typical excitotoxic retinal lesions were produced by the agonists and, at the lower concentrations tested, revealed a regional sensitivity. There was a positive correlation between the amount of gamma-aminobutyric acid release and the extent of tissue swelling, suggesting that release may be secondary to toxic cellular events. Omission of Cl- completely blocked cytotoxic effects due to kainate or glutamate. Likewise, addition of the Cl-/bicarbonate anion channel blocker 4,4'-diisothiocyanatostilbene-2,2'-disulfonate at 600 microM protected retina from cytotoxic damage from all excitotoxic analogs and restored amino acid levels to baseline values. Furosemide, which blocks Na+/K+/2Cl- cotransport, was only minimally effective in reducing amino acid release induced by the agonists. Consistent with the latter, histological examination showed the continued presence of the lesion but with general reduction of cellular edema. These results indicate that although influx of Cl- is a central component of the acute excitotoxic phenomenon, mechanisms other than passive Cl- flux may be involved.

Astrocytic swelling in traumatic-hypoxic brain injury. Beneficial effects of an inhibitor of anion exchange transport and glutamate uptake in glial cells

Swelling of brain slices is shown to occur in response to elevated potassium levels or glutamate, which is accompanied by astrocytic swelling. Cl-/HCO3- anion exchange inhibitors, such as SITS (4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid) or furosemide, but not the specific cotransport inhibitor bumetanide, inhibit swelling or increased ion uptake in rat brain slices caused by elevated potassium although there were marked species differences in sensitivity. A novel anion exchange inhibitor, L-644,711, inhibits swelling and increased ion uptake caused by glutamate in rat and cat brain slices, as well as inhibiting [3H]glutamate uptake in primary rat astrocyte cultures. Possible mechanisms of action of the inhibitors are discussed. L-644,711 was also found to be effective in promoting recovery from a trauma plus hypoxia head injury model in cats. Marked perivascular astrocytic swelling is associated with this head injury model, and L-644,711 also inhibited such astroglial swelling as determined ultrastructurally. The significance of these findings in relation to possible connections between astrocytic swelling and brain pathology is discussed.

Spatiotemporal gradients of kainate-sensitivity in the developing chicken retina

We have studied the age-dependence of the effects of kainate (KA) on the chick retina as a prelude to the accompanying paper on the effects of target-removal on the isthmo-optic nucleus. KA was injected into the eyes of chick embryos and chicks at different ages, and the retinas were fixed a few hours or several days later. The former group of retinas was scanned for pyknotic cells. The earliest age at which KA caused pyknosis was embryonic day 10 (E10), when pyknotic cells appeared in a ventrotemporal patch in the amacrine sublayer near the fundus. Over the next two days the sensitive region expanded tangentially, reaching the periphery first temporally, then nasally. Only after E12 did the KA cause pyknotic cells to occur also in the bipolar sublayer, where the sensitivity spread in the same spatiotemporal sequence as the initial wave, but two days later. Cell loss was examined in embryos that survived a week or more after the KA injection. Substantial cell depletion was found in both the inner nuclear and ganglion cell layers, but only when the injection had been made after E12. With progressively later injections, the depleted zone expanded in the same spatiotemporal sequence as described above, until at E15 the injections caused depletion throughout the entire extent of the retina. The reasons for the lack of cell depletion after KA injections made before E12 are discussed. Cell counts in the ganglion cell layer and studies of anterograde transport of intravitreally injected peroxidase along the retinofugal fibers showed that about half the ganglion cells (including the displaced ganglion cells) pass through a period of vulnerability to the KA injections, to which they subsequently become sensitive.

Evidence for gluconeogenesis in the amphibian retina

Evidence for the existence of a gluconeogenic pathway was provided in the amphibian retina. It was found that [3H]glutamate was converted to [3H]glucose derived from [3H]glutamate was incorporated into glycogen. The rate for this incorporation was found to be essentially the same in both light- and dark-adapted retinas: 0.147 vs. 0.142 nmol (mg protein X 2 hr)-1, respectively. However, the rate of incorporation was found to decline progressively with time. The rate for the incorporation of label derived from glutamate into glycogen was found to be considerably less than that for [3H]glucose: 10.2 nmol (mg protein X 2 hr)-1. The activity of a key gluconeogenic enzyme, fructose-1,6-bisphosphatase, also was demonstrated in retinal supernatants, approximately 1 nmol (mg X min)-1, and the activity of this enzyme was found to be inhibited both by adenosine monophosphate and by fructose-2,6-bisphosphate.

Effects of arachidonic acid on glutamate and gamma-aminobutyric acid uptake in primary cultures of rat cerebral cortical astrocytes and neurons

The effects of arachidonic acid on glutamate and gamma-aminobutyric acid (GABA) uptake were studied in primary cultures of astrocytes and neurons prepared from rat cerebral cortex. The uptake rates of glutamate and GABA in astrocytic cultures were 10.4 nmol/mg protein/min and 0.125 nmol/mg protein/min, respectively. The uptake rates of glutamate and GABA in neuronal cultures were 3.37 nmol/mg protein/min and 1.53 nmol/mg protein/min. Arachidonic acid inhibited glutamate uptake in both astrocytes and neurons. The inhibitory effect was observed within 10 min of incubation with arachidonic acid and reached approximately 80% within 120 min in both types of culture. The arachidonic acid effect was not only time-dependent, but also dose-related. Arachidonic acid, at concentrations of 0.015 and 0.03 mumol/mg protein, significantly inhibited glutamate uptake in neurons, whereas 20 times higher concentrations were required for astrocytes. The effects of arachidonic acid were not as deleterious on GABA uptake as on glutamate uptake in both astrocytes and neurons. In astrocytes, GABA uptake was not affected by any of the doses of arachidonic acid studied (0.015-0.6 mumol/mg protein). In neuronal cultures, GABA uptake was inhibited, but not to the same degree observed with glutamate uptake. Lower doses of arachidonic acid (0.03 and 0.015 mumol/mg protein) did not affect neuronal GABA uptake. Other polyunsaturated fatty acids, such as docosahexaenoic acid, affected amino acid uptake in a manner similar to arachidonic acid in both astrocytes and neurons. However, saturated fatty acids, such as palmitic acid, exerted no such effect. The significance of the arachidonic acid-induced inhibition of neurotransmitter uptake in cultured brain cells in various pathological states is discussed.

Short- and long-term consequences of intracranial injections of the excitotoxin, quinolinic acid, as evidenced by GFA immunohistochemistry of astrocytes

Astroglial reactions to intrastriatal and intrahypothalamic injections of the endogenous excitotoxin quinolinic acid (50 micrograms in 1 microliter) were studied in adult rats, using immunohistochemistry with antiserum to glial fibrillary acidic protein. Animals were sacrificed 6 h, 24 h, 3, 7 and 30 days or 1 year after the injection. Six and 24 h after quinolinic acid, the amount of glial fibrillary acidic protein-like immunoreactivity in the injected striatum was lower than in controls but returned to a normal level at 3 days. Not until 7 days was a clear striatal gliosis apparent, as evidenced by an increased density of glial fibrillary acidic protein-positive structures and brightly fluorescent, clearly hypertrophic cells. This gliosis was even more developed in animals sacrificed 30 days postoperatively. A weak astrocytic reaction was also observed in the ipsilateral corpus callosum at 6 h after quinolinic acid. By 3 days, a marked gliosis restricted to the injected hemisphere was present throughout corpus callosum and cortex cerebri. In animals sacrificed 30 days after quinolinic acid the extrastriatal astrocytic reaction was clearly diminished, although the striatal gliosis was still prominent. One year postinjection, no obvious gliosis could be observed in cortex cerebri or corpus callosum while striatal tissue, now markedly reduced in volume, was clearly gliotic. Using neurofilament antiserum, increased fluorescence intensity was noted in striatal nerve bundles during the first day after an intrastriatal quinolinic acid injection and persisted 1 year postoperatively. Controls were similarly injected with an equimolar amount of nicotinic acid, the non-excitatory, non-neurotoxic decarboxylation product of quinolinic acid. No changes in immunoreactivity of glial fibrillary acidic protein or neurofilament were found in these animals. In animals treated intrahypothalamically, a spherical central area almost devoid of glial fibrillary acidic protein-immunoreactivity was noted around the injection site 7 days after quinolinic acid administration. Around this area, gliosis was observed. Apart from a very restricted gliotic reaction around the needle tract, no astrocytic reaction was observed in nicotinic acid-injected control animals. We conclude that quinolinic acid causes both reversible and long-lasting gliosis when injected into the rat striatum. As a natural brain metabolite, quinolinic acid may constitute a particularly valuable tool for the elucidation of a possible role of glia in neurodegenerative disorders.

Glutamate and kainate are not directly toxic to developing amacrine cells: analysis in a Lucifer Yellow-labeled population

Lucifer Yellow (LY)-labeled retinal amacrine cells were examined for toxin sensitivity to glutamate (Glu) or kainate (KA) and for high-affinity uptake (HAU) of Glu. In vitro, a 24-h exposure to either toxin caused a 50% loss of neurons with no loss of LY neurons. A 1-h exposure of intact retina to the toxins resulted in a two-fold increase in non-viable cells with no change in LY neurons. While histological damage within the retina was seen following toxin exposure, the LY population appeared unaffected. HAU in vitro was found in 5% of neurons but never colocalized with LY neurons. These studies show that Glu and KA do not directly affect the LY-labeled amacrine cells and support the hypothesis that their eventual loss may be an indirect consequence of toxin exposure.

Stimulation of photoreceptor disc shedding and pigment epithelial phagocytosis by glutamate, aspartate, and other amino acids

It has been reported that aspartate and glutamate selectively impair the structure (Olney, '82) and function (e.g., Furakawa and Hanawa, '55) of second- and third-order retinal neurons while leaving the photoreceptor unaffected. Either amino acid may mimic the endogenous photoreceptor neurotransmitter (Ehinger, '82). We report here that excitatory amino acids also induce massive rod photoreceptor disc shedding in eyecups of Xenopus laevis maintained in vitro. Disc shedding is the process whereby photoreceptors eliminate effete discs. It involves interaction between the distal outer segment and pigment epithelium. Millimolar L-aspartate and L-glutamate, as well as micromolar kainic acid, a glutamate analog, stimulate disc shedding three- to fivefold higher than normal light-evoked shedding levels and result in extensive inner retinal damage. Fifty-millimolar KCl, 1.0 microM ouabain, and replacement of sodium with choline also stimulate disc shedding and alter retinal structure. Extensive neurotoxicity appears unrelated to disc shedding since other amino acids having no significant or marginal effects on retinal structure also stimulate shedding. While the site and mechanism of action of these effectors, and in particular the excitatory amino acids, is now undefined, the data show that amino acids thought to act directly and specifically on inner retinal neurons can also markedly alter photoreceptor and pigment epithelial metabolism.

Mg2+ reduces N-methyl-D-aspartate neurotoxicity in embryonic chick neural retina in vitro

N-Methyl-D-aspartate (NMDA) is a potent neurotoxin that affects cells in the inner layers of the embryonic chick retina exposed in vitro. After exposure of the embryonic day 12 neural retina to 0.5-10.0 mM NMDA for 30 min, 50-80% of the cells in the inner region of the inner nuclear layer and 50-100% of the cells in the ganglion cell layer were hypochromatic. When retinas were incubated with Mg2+ (0.5-10.0 mM) for 15 min and then incubated with Mg2+ and NMDA (0.5 mM) for 30 min, the NMDA effect in the inner layers was dramatically reduced but not abolished. Removal of Mg2+ before NMDA exposure produced retinas as seriously affected as retinas not exposed to Mg2+. Studying the effects of NMDA inhibitors, such as Mg2+, may help elucidate the mechanism of the cytotoxic events that occur in the retina in response to certain excitatory acidic amino acids.

The role of brain edema in epileptic brain damage induced by systemic kainic acid injection

Edema formation and blood-brain barrier permeability was studied in animals with epileptic seizures induced by subcutaneous injection of kainic acid. Brain edema was most pronounced between 3 and 24 h after kainic acid injection. It was reflected by massive swelling of perineuronal and perivascular astroglia. Three hours after kainic acid perivascular astroglia swelling resulted in disturbance of local microcirculation in the affected brain areas. In addition, compression of drainage veins by the edematous brain induced focal perivenous hemorrhages similar to herniation damage in human brain edema. Tracer studies with sodium fluorescein, Evans blue, albumin and horseradish peroxidase revealed only a mild increase in the permeability of cerebral vessels, topographically unrelated to areas of brain edema. This finding indicates the presence of cytotoxic brain edema in kainic acid-induced epileptic brain damage. Treatment of brain edema with dexamethasone did not influence the incidence and severity of kainic acid-induced epileptic brain damage. However, in 54% of animals injected with kainic acid, lesions were completely prevented by treatment of brain edema with mannitol. The present results indicate that brain edema plays an important role in the pathogenesis of epileptic brain damage following systemic kainic acid intoxication. It is suggested that in this model of limbic epilepsy the brain edema is due to the massive ionic imbalance elicited in the affected brain regions by the kainic acid-induced persistent neuronal excitation.

Gliotoxic effects of alpha-aminoadipic acid on monolayer cultures of dissociated postnatal mouse cerebellum

The cytotoxic effects of DL-, D- and L-alpha-aminoadipic acid, a six-carbon homologue of glutamate, were investigated in cell cultures of dissociated postnatal mouse cerebellum. Treatment with alpha-aminoadipic acid resulted in rapid nuclear and cytoplasmic swelling and, after longer periods of exposure, karyopyknosis of astrocytes, identified by indirect immunofluorescence labelling with anti-human glial fibrillary acidic protein antiserum. The number of astrocytes with pyknotic nuclei depended on the concentration of alpha-aminoadipic acid as well as on the duration of drug action. The presence of 0.21 mM DL-alpha-aminoadipic acid or 0.10 mM L-alpha-aminoadipic acid for 40 h caused karyopyknosis in 50% of the astrocytes. In contrast, D-alpha-aminoadipic acid, had little gliotoxic activity. None of the cytotoxic effects of DL-alpha-aminoadipic acid or L-alpha-aminoadipic acid observed for astrocytes were seen for the neurons present in the cultures when the drug was added after 4 days in vitro. Neurotoxic effects were evident, however, when alpha-aminoadipic acid was included in the culture medium at plating. These results indicate that alpha-adminoadpic acid can be used to substantially reduce the number of astroglia in cerebellar cultures and that dissociated cell cultures will provide a useful model with which to study the mechanisms of alpha-aminoadipic acid induced glial toxicity.

Sensitive and insensitive states of cultured glioma cells to glutamate damage

Cytotoxic effects of L-glutamate and related compounds were investigated on rat glioma C6 cells in vitro. Within 12-24 h, addition of glutamate to the culture medium, resulted in degeneration of the C6 cells. The ED50 for glutamate-induced damage was about 4 mM. Seventeen structural analogues of glutamate, including agonists and antagonists for glutamate receptors as well as glutamate-uptake inhibitor, were examined concerning their toxicity on C6 cells. Among them, L-aminoadipic acid, DL-aminopimelic acid, DL-homocysteic acid, L-cysteic acid, quisqualic acid, L-glutamic acid diethyl ester and 2-amino-4-phosphonobutyric acid elicited similar degeneration at comparable concentrations. The D-isomer of glutamate was not cytotoxic. Following differentiation of C6 cells with 1 mM dibutyryl cyclic AMP or 3 mM sodium butyrate, they were no longer susceptible to L-glutamate and L-aminoadipate. C6 cells treated with 10 microM hydrocortisone, which is known to induce glutamine synthetase activity, were also resistant to L-glutamate, but not to L-aminoadipate. The decomposition of cellular DNA in glutamate-treated cultures was confirmed by flow cytometer analysis. The results demonstrate that the sensitivity of C6 cells to glutamate-induced cytotoxicity was modified by cellular metabolic conditions. This indicates that cultured glioma C6 cells are a useful model system to investigate the molecular mechanism of glutamate gliotoxicity in vitro.

Effect of D, L-alpha-aminoadipate on the mediobasal hypothalamus and endocrine function in the rat

Using the glutamate analog, D,L-alpha-aminoadipic acid (D,L-alpha AA), experiments were conducted to examine the nature, extent, and specificity of its toxicity in the mediobasal hypothalamus and to determine its effect on endocrine homeostasis. Neonatal rats received daily injections of D,L-alpha AA (4 g/kg BW) on postnatal days 5-10 and were killed at various post-treatment intervals. Sex-matched littermates were given equimolar amounts of NaCl and served as controls. Treated rats killed 18 days post injection weighed slightly less than controls and had reduced testicular, ovarian, and uterine weights, but the differences were not statistically significant. In D,L-alpha AA treated rats serum and pituitary levels of TSH and PRL were comparable to control values. Pituitary content of LH (male's and female's) and FSH (female's), however, was lower (P less than 0.05) in D,L-alpha AA treated rats than in controls, but serum levels were not significantly different. Distinct cytopathologic changes were evident in the arcuate nucleus and median eminence of D,L-alpha AA-treated rats killed at 2 and 6 h post injection only. By 12 h evidence of acute damage had largely disappeared. Both glial and ependymal cells underwent edematous swelling and necrosis, but neurons were largely unaffected. Evidence of reactive changes, such as gliosis, infiltration of microglia, and removal of debris, however, were not very conspicious. A random sample of mediobasal hypothalami of rats killed 18 days post injection failed to show any detectable lesion or residual effects of earlier pathology. Age at the time of exposure to the gliotoxin was found to be an important variable affecting both extent and duration of injury. The most deleterious effects were observed when the gliotoxin was administered in the form of a single injection on postnatal day 5 only. The results suggest that normal neuronal activity and endocrine homeostasis, specifically gonadotropin, may be irreversibly altered as a consequence of transient disruption of the glial compartment.

Aspartate-induced dissociation of proximal from distal retinal activity in the mudpuppy

The effects of aspartate (Asp) on the ERG and on neuronal, glial, and K+ responses were monitored continuously in the superfused mudpuppy eyecup. Asp induced a time-dependent sequence of events which may be divided into three stages: Stage 1, initially, light-evoked responses throughout the retina are depressed; Stage 2, distal responses (horizontal, bipolar, and K+ responses) return to near pre-drug amplitudes and there is a simultaneous ERG enhancement, but responses in the proximal retina remain suppressed; Stage 3, a second depression of retinal responses leads to a-wave isolation. The dissociation of distal from proximal responses observed during Stage 2 strongly supports the hypothesis that the ERG b-wave results from events arising in the distal retinal network.