(Received for publication, October 1, 1996, and in revised form, February 21, 1997)
From Neurex Corporation, Menlo Park, California
94025, the ¶ Department of Anesthesiology, Stanford University
Medical School, Stanford, California 94305, and the
Department
of Biochemistry and Molecular Biology, Colorado State University,
Fort Collins, Colorado 80523
Elevated extracellular concentrations of the excitatory transmitter glutamate are an important cause of neuronal death in a variety of disorders of the nervous system. The concentrations and rates of clearance and production of extracellular glutamate were measured in the medium of primary cultures from mouse neocortex containing neurons, astrocytes, or both cell types. Measurements were performed in the presence and absence of 2 mM glutamine with or without neuronal injury caused by 5-h exposure to hypoxia or 500 µM N-methyl-D-aspartate or a freeze-thaw cycle. High rates of glutamate generation (0.5-0.8 µM/min in the 0.4-ml culture well) occurred if neurons were both damaged and exposed to glutamine. Intact neurons or glia exposed to glutamine generated only small amounts of glutamate (0.03 µM/min). Glutamate generation by damaged neurons was dependent on the presence of glutamine, activated by phosphate, and inhibited by 6-diazo-5-oxo-L-norleucine and p-chloromercuriphenylsulfonic acid (pCMPS), strongly implicating the mitochondrial glutaminase. Following 5-h exposure to 500 µM N-methyl-D-aspartate, the glutaminase was localized to fragments of damaged neurons and was accessible to inhibition by the membrane-impermeant pCMPS. The glutaminase activity from damaged neurons is sufficient to account for the neurotoxic concentrations of glutamate in hypoxic mixed neuronal-glial cultures exposed to 2 mM glutamine. Finally, pCMPS is neuroprotective and also prevents the increased rate of generation of glutamate observed in neuronal cultures after prolonged exposure to glutamine. The cumulative data indicate the following: 1) excitotoxic neuronal death activates the hydrolysis of extracellular glutamine by the mitochondrial glutaminase, and 2) the glutaminase in damaged neurons is sufficient to cause neuronal death in in vitro models of neuronal injury.
Excess extracellular concentrations of the neurotransmitter glutamate contribute to neuronal damage in such conditions as cardiac arrest, stroke, and seizures (1-4). Although this is well established, the sources of glutamate responsible for pathological effects are incompletely described. In the early phase of hypoxia (minutes), transmitter glutamate is released in vivo (5, 6). However, there is increasing evidence for a delayed component to glutamate-mediated neuronal damage in brain ischemia. Glutamate receptor antagonists are neuroprotective even if given hours after reversible focal ischemia (7, 8) as well as global ischemia (9). This is consistent with the large delayed increase in extracellular glutamate observed after both reversible and permanent focal occlusion of the middle cerebral artery (10, 11). The cellular sources responsible for this delayed glutamate production remain to be characterized.
The mitochondrial glutaminase, which catalyzes the enzymatic conversion of glutamine to glutamate, is both an important contributor to transmitter pools of glutamate (12, 13) and the predominant glutamine-utilizing enzyme of the brain (14). In brain, the enzyme is present in higher amounts in neurons than in glia (15, 16). The glutaminase is highly compartmentalized, being localized to the inner mitochondrial membrane (17-19). Glutamine is the amino acid in highest concentration in the brain extracellular fluid (20) and provides an abundant substrate for the enzyme in vivo.
Several previous studies have suggested a role for glutamine and glutamine hydrolysis in excitotoxicity in cell culture. When neurons were cultured with reduced numbers of astrocytes, glutamine was found to be toxic coincident with increased extracellular glutamate. Both glutamine toxicity and glutamate generation were blocked by an NMDA1 receptor antagonist (21). The medium of damaged neuronal cultures (22) was found to possess glutamine hydrolysis activity, which is particulate and blocked by the glutamine affinity-labeling reagent 6-diazo-5-oxo-L-norleucine (23). Finally, glutamine potentiated hypoxic neuronal death in mixed glial/neuronal cultures (24), and toxicity was again inhibited by glutamate antagonists.
The above studies provide reasons to form the hypothesis that the mitochondrial glutaminase may contribute to glutamate generation and neuronal injury in vitro. However, further information is required to evaluate the relative importance of the enzyme in these processes. Likewise, the cellular location of the enzyme that contributes most significantly to glutamate production has not yet been determined in neuronal injury paradigms. In this study, experiments are performed that test the hypothesis that 1) The production of glutamate from glutamine following neuronal death is significant by comparison with other cellular sources of glutamate in primary cultures of mouse cortex, and 2) The mitochondrial glutaminase is the enzyme responsible for this activity. Additional experiments address the cellular compartment of active glutaminase after neuronal death, as well as the role of the enzyme in in vitro neuronal injury paradigms.
Eagle's minimal essential medium, containing 1 mM phosphate but not bicarbonate or glutamine, was purchased from Life Technologies, Inc. Horse and fetal bovine serum were obtained from Hyclone Laboratory Inc. All other tissue culture reagents were from Sigma.
Primary cultures of cerebral cortical cells were prepared from Swiss Webster mice (Simonsen Laboratories). All animal use procedures were in strict accordance with the National Institutes of Health guidelines (41); all protocols were approved by the Stanford University Institutional Animal Care and Use Committee.
Cultures of pure cortical neurons and mixed cultures of neurons and astrocytes were prepared by modifications of the procedures of Dichter (25) and Choi et al. (26) as described previously (27). Astrocytes were cultured from cortical cell suspensions from 1-2-day-old Swiss Webster mouse pups. Mixed cultures of neurons and astrocytes were obtained by plating cortical neurons from embryonic day 15 or 16 mice on confluent astrocyte monolayers. Pure neuronal cultures were made from the same embryonic cortical cell suspensions; astrocyte growth was inhibited by adding cytosine arabinoside and decreasing serum in the medium. For survival, neuronal cultures were fed with glial conditioned medium. Neuronal cultures were used for experiments at 11-15 days in vitro, and mixed cultures were used at 13-15 days after plating the neurons.
HypoxiaHypoxia was carried out at 37 °C in an anoxic chamber (<0.2% oxygen; Forma Scientific). Before each experiment, the medium was preequilibrated with an anoxic gas mixture containing 5% CO2, 85% N2, and 10% H2 and incubated at 37 °C. Cells were deprived of oxygen by triple exchange (approximately 1:1000 dilution) of the culture medium with deoxygenated minimal essential medium, with or without the addition of glutamine, to the indicated concentration. The oxygen tension in the anoxic chamber was monitored using an oxygen electrode (model MI-730; Microelectrodes Inc.). After 5 or 7 h of hypoxia, the cultures were returned to the normoxic incubator.
GlutamineGlutamine was purchased from Bachem or from Life
Technologies, Inc. To avoid possible complications from glutamate
toxicity, glutamate was removed from the Bachem glutamine by passage of a 50 mM solution over a 3 × 100-cm column of
diethylaminoethyl-Sepharose (Pharmacia Biotech Inc.) at pH 5.0. The
resulting glutamine stock contained less than 0.2 µM
glutamate in a 2 mM solution and was used in the
experiments with the pure neurons and to show glutamine toxicity in
hypoxic mixed cultures. Glutamine from Life Technologies contained 1-2
µM glutamate in a 2 mM solution and was used
in some of the experiments with the mixed cultures (where the small amount of added glutamate is rapidly removed). Glutamine solutions were
stored at concentrations of 50 mM or greater at
20 °C.
Precolumn
derivatization with o-phthalaldehyde (Sigma) and separation
by reversed phase HPLC was used. HPLC instrumentation was as described
previously (28), with the addition of a Hewlett-Packard model 1046A
fluorimetric detector (excitation 340 nm, emission 420 nm). Medium was
collected from cell culture at various times and frozen at 80 °C,
prior to dilution of 5 or 10 µl into autosampler vials containing 40 or 45 µl of dimethylformamide:water, 1:3 (derivatives with
2-mercaptoethanol) or 1:9 (derivatives with
N-acetyl-L-cysteine). For analysis of the
derivatives formed with 2-mercaptoethanol (29), samples were reacted as
described previously (28), and a gradient of 0-40% methanol in 1.25 mM sodium phosphate, pH 6.2, over 20 min was used to elute
the derivatives from a 4.5 × 250-mm Beckman Ultrasphere
octadecylsilica column (dp 5 µm) at 1 ml/min. For analysis of the
derivatives formed with N-acetyl-L-cysteine (30), samples were reacted with 25 µl of 1 mg/ml
o-phthalaldehyde and 50 µl of 1 mg/ml
N-acetyl-L-cysteine (Fluka) in 0.5 M
potassium borate, pH 10.0. Chromatography was over a 4.5 × 250-mm
Phenomonex Primesphere "HC" octadecylsilica column (dp 5 µm)
using a gradient of 0-35% methanol in 15 mM sodium
phosphate, pH 6.2 (0.13% tetrahydrofuran), over 65 min at 1 ml/min. It
was shown for each of the experimental conditions (i.e..
glial and control and damaged neuronal and mixed cultures) that both
analytical systems gave results for glutamate and glutamine
measurements that were, within error, identical.
Neuronal cultures were exposed to 500 µM NMDA or control conditions for 5 h, at which time
the medium was removed from the cellular layer and both were stored at
80 °C. The media from single wells (300 µl) were centrifuged at
100,000 × g for 40 min. The resulting pellets were
resuspended in 40 µl of sample loading buffer and subjected to
SDS-gel electrophoresis. The cells from a single well were resuspended
in 100 µl of sample loading buffer, and 20 µl were used. Gel
electrophoresis and Western blotting was performed as described (31)
except that the immune complex was detected using the enhanced
chemiluminescence system (Amersham). The relative intensities of the
resulting bands were determined by densitometric analysis using a
Microscan 2000 densitometer.
Neuronal death was measured by assay of lactate dehydrogenase (LDH) activity released into the culture medium (32) and was also independently assessed by light microscopy for all experiments. The amount of LDH released was expressed as the ratio of LDH activity in the medium to the amount released from the same cultures after induction of complete neuronal death at the end of the experiment. In the mixed neuronal-glial cultures, total neuronal LDH was defined as enzyme released after 24-h exposure to 500 µM NMDA. In neuronal cultures, neuronal LDH release was measured after freeze-thaw. In the neuronal cultures, LDH release by the NMDA exposure method is normally about 85% of that obtained by freeze-thaw.
Expression of Glutamate Amounts and Production RatesGlutamate was measured in units of pmol/µl of culture medium, or µM. In the absence of cellular uptake (i.e. in damaged neuronal cultures), the rate of glutamate production was obtained directly from the measurements of the amounts of glutamate in culture medium at various times.
Experiments on the clearance of glutamate from culture medium showed
first order kinetics in intact glial, neuronal, and mixed cultures.
This allows expression of medium glutamate concentrations according to
the equation (see Ref. 33), d[Glu]/dt = S k[Glu], where [Glu], in units of
µM, is the concentration of glutamate in the 0.4 ml of
medium in a culture well, S (in µM/min) is the rate of addition of glutamate to the culture medium from cellular sources, and k (in min
1) is the empirically determined
rate constant for clearance. Pseudo-first order kinetics are expected
for the clearance of glutamate at concentrations significantly below
the Km for cellular uptake (about 45 µM; Refs. 34 and 35). Although the value of k
is proportional to cell (carrier) density, little variation is expected
in cultures containing glia, since glial cultures are confluent.
In cultures where glutamate concentrations are (within error) constant, d[Glu]/dt is close to 0, and cellular production of medium glutamate is balanced by its removal, such that glutamate production can be calculated from the steady state equation, S = k[Glu].
Calculations were performed using the slopes of the regression lines
that describe the rate constants for glutamate removal (Fig. 1) and the
mean values for culture medium glutamate concentrations. Because of the
relevance to data on glutamate toxicity, rates of glutamate production
are given with units of concentration over time. For comparative
purposes, glutamate production rates are also given in the text as the
pmol of glutamate produced per min in each culture. These values were
obtained after multiplication by the volume of culture medium.
Measures of culture medium and total cellular lactate dehydrogenase activity (above) were performed for all experiments and were used to verify that systematic variations in neuronal density did not affect the results; essentially identical results were obtained for data in Tables I, II, III if normalized to mean total culture LDH release. The mean of the total neuronal LDH was 259 units with pure neuronal cultures (n = 116) and 776 units with the mixed cultures (n = 99). The coefficient of variation of the LDH measurements was 0.38 in both culture systems.
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All data are expressed as the mean and S.E. Each n value represents data from one culture well. Where not given in the text, values for n are given in the tables. Unless otherwise indicated, an n value of 4-6 culture wells was used for each condition in each experiment, with repetitions carried out using at least three independent dissections for each experiment. Statistical comparisons were performed by the standard t test for the comparison of the means of two populations.
Initial experiments were performed to measure the rates of glutamate uptake and production in intact and damaged cultures of pure neurons. The steady state concentration of glutamate in the medium of neuronal cultures was 0.38 ± 0.05 µM. In preliminary experiments, neuronal cultures were subjected to a freeze-thaw cycle to completely lyse the cells. The medium glutamate concentration was increased to 4.5 ± 0.5 µM (n = 8). Thus, lysis of the neuronal cultures released approximately 1.8 nmol of glutamate into the 0.4 ml of culture medium. Much of this presumably represents the large amount of glutamate that is stored as a neurotransmitter. Subsequently, the lysed cultures were incubated with 50 µM glutamate. In all cases (n = 8), the concentration of glutamate in the medium after 2 h was altered by less than 5%. The stability of glutamate in the medium of damaged cultures indicated that the enzymatic degradation of glutamate in the culture medium was not significant. Thus, the rates of glutamate clearance and production could be measured directly.
As shown in Fig. 1, the clearance of glutamate from the
medium of intact neuronal cultures could be described by a first order process with an apparent kinetic constant of 0.012 min1.
Thus, the intact neuronal cultures exhibit a relatively slow rate of
glutamate uptake. Fig. 2 illustrates the time course of appearance of glutamate in the cell culture medium of intact pure neuronal cultures or of cultures lysed by a freeze-thaw cycle, both in
the presence and absence of 2 mM glutamine. In the absence of added glutamine, glutamate concentrations in intact neuronal cultures are maintained at below 1 µM. Under these
conditions, the rate of glutamate production calculated from the steady
state equation is 0.0046 µM/min (1.8 pmol/min). Thus, the
production of glutamate by neurons cultured in the absence of added
glutamine is also very slow and is small in comparison with the total
cellular content of glutamate.
If 2 mM glutamine is added to intact neuronal cultures, the rate at which glutamate accumulates in the culture medium increases with time (Fig. 2). Since the clearance of medium glutamate by neuronal cultures is extremely slow, one estimate of the rate of glutamate production by neurons exposed to glutamine can be obtained from the initial rate of glutamate accumulation. Using the difference in glutamate concentrations at 1 and 15 min after the glutamine addition, a value of 0.032 ± 0.006 µM/min (12.8 pmol/min) was obtained. Since glutamine exposure itself eventually causes neuronal death and high rates of glutamine hydrolysis, this estimate of glutamate production should be viewed as an upper limit. However, this value is similar to that obtained by comparing glutamate production by glial and mixed neuronal-glial cultures exposed to glutamine (see below).
In contrast, the rate of glutamate production by damaged cultures of pure neurons exposed to glutamine is very rapid and is linear with time. In the absence of added glutamine (i.e. in the 0.15 mM glutamine manufactured by the neuronal cultures), glutamate production into the medium of cultures lysed by freezing and thawing occurred at a rate of 0.035 ± 0.006 µM/min (14 pmol/min). However, the addition of 2 mM glutamine to the medium of freeze-thawed cultures resulted in the much higher rate of glutamate production of 0.79 ± 0.08 µM/min (316 pmol/min). Similarly, neuronal cultures that were subjected to "excitotoxic" injury by treatment for 5 h with 500 µM of the glutamate receptor agonist NMDA and then incubated with 2 mM glutamine produced glutamate in the culture medium at a rate of 0.54 ± 0.09 µM/min (216 pmol/min). Thus, damaged neurons incubated in 2 mM glutamine produce within 6-8 min an amount equal to that released by freeze-thawing. The various rates and rate constants measured with neuronal cultures are summarized in Table I.
Glutamate Production by Glial CulturesWhen incubated with 15 µM glutamate, pure cultures of intact astrocytes exhibit
a rapid uptake of glutamate that is described by a first order rate
constant of 0.083 min1 (data not shown). This is
consistent with previous reports (34, 35) and shows that uptake of
glutamate by the glial cultures is about 7 times faster than that of
the neuronal cultures. The glutamate concentration of glial cultures
was maintained below 1 µM when cells were maintained in
the absence or presence of 2 mM added glutamine or when
subjected to hypoxic conditions (see below). The medium glutamate
concentration remained unchanged between 7 and 24 h after medium
change and was 0.14 ± 0.04 µM and 0.36 ± 0.06 µM in medium containing 0.15 mM or 2.0 mM glutamine, respectively. Based on these steady state
concentrations and the measured rate of glutamate uptake, the rates of
glutamate production in the absence and presence of added glutamine
were calculated to be 0.012 µM/min (4.8 pmol/min) and
0.030 µM/min (12 pmol/min), respectively. Thus, the
calculated rates of glutamate production by glial cultures are only
slightly affected by the addition of glutamine and are similar to those
observed in intact neurons cultured in the absence of added glutamine.
The various rates and rate constants measured for cultures of pure
glial cells are summarized in Table II.
Added
glutamate (15 µM) was rapidly cleared from the medium of
the mixed glial-neuronal cultures (Fig. 1). The uptake again fit to a
first order process and occurred with a rate constant of 0.072 min
1. The observed rate constant suggests that the glial
cells constitute the primary site of glutamate uptake in the mixed
cultures. When the intact mixed cultures were maintained in the absence
or presence of added 2 mM glutamine, they also maintained
steady state concentrations of glutamate below 1 µM
(0.37 ± 0.06 µM and 0.83 ± 0.47 µM, respectively). Thus, from the steady state equation,
the rates of glutamate production were estimated to be 0.027 µM/min (11 pmol/min) in the absence of added glutamine
and 0.060 µM/min (24 pmol/min) in the presence of 2 mM glutamine. The various kinetic constants measured for intact glial-neuronal cultures are summarized in Table II.
Glutamate production by intact neurons exposed to glutamine can be estimated from the difference in the steady state rates of glutamate production by glial and mixed glial-neuronal cultures exposed to glutamine. This value of 0.030 µM/min (12 pmol/min) agrees well with the initial rate of production of glutamate by pure neuronal cultures exposed to glutamine (above).
Glutamine Hydrolysis after Neuronal Death Has the Characteristics of the Mitochondrial GlutaminaseThe above experiments defined glutamine hydrolysis by damaged neurons to be the most significant source of glutamate production in our primary cultures of mouse neocortex. Subsequent experiments were performed to determine if the hydrolysis was caused by the mitochondrial glutaminase.
This hypothesis was tested by asking if glutamine hydrolysis following
neuronal damage was activated by phosphate (36, 37) and inhibited by
the glutamine affinity-labeling reagent,
6-diazo-5-oxo-L-norleucine (DON) (23). Fig.
3 illustrates the time course of accumulation of
glutamate in mixed neuronal-glial cultures incubated in a
phosphate-free saline following selective damage of neurons by
pretreatment with NMDA. Glutamate generation is dependent on the
presence of added 2 mM glutamine and increased 8-fold by
the inclusion of 20 mM phosphate. The addition of 2 mM DON contributes about 5 µM glutamate as a
contaminant, which is removed by glial uptake. The added DON inhibits
90% of the glutamate production observed in the presence of 2 mM glutamine and 20 mM phosphate. In contrast,
DON inhibits only 50% of the lower amount of glutamate production
observed in the absence of added phosphate. This lesser extent of
inhibition at low phosphate is consistent with the decreased inhibition
of the purified renal glutaminase by DON that is observed at
lower phosphate concentrations (23).
To substantiate the results with DON and phosphate in NMDA-damaged mixed cultures, glutamine hydrolysis by damaged pure neuronal cultures was studied. Table III summarizes rates of glutamate generation following exposure to 500 µM NMDA for 5 h. As with the mixed cultures, glutamate generation is dependent on the presence of glutamine and activated (6-fold) by the inclusion of 20 mM phosphate. The addition of 2 mM DON inhibited 90% of the glutamate generation with 20 mM phosphate, and 67% of that without added phosphate. Similar results were obtained in an experiment with pure neuronal cultures damaged by freeze-thaw (data not shown).
The effects of the thiol-reactive and membrane-impermeant mercurial
compound p-chloromercuriphenylsulfonate were next
determined. This reagent inhibits the glutaminase in permeabilized but
not intact renal mitochondria (17). Fig. 4 illustrates
results of an experiment in which pure neuronal cultures were first
either incubated under control conditions or were damaged by exposure to NMDA. Following this, 2 mM glutamine was added to both
sets of cultures, and the effects of 30 µM pCMPS on the
resulting generation of glutamate were then assayed. As illustrated for
a shorter time period in Fig. 2, the exposure of healthy neurons to 2 mM glutamine resulted in steadily increasing rates of
glutamate generation (Fig. 4, upper panel, curve
1). This delayed hydrolysis of glutamine was prevented by the
inclusion of 30 µM pCMPS in the culture medium (curve 2). NMDA treatment of neurons resulted in rapid
hydrolysis of added glutamine, and this was almost completely inhibited
by 30 µM pCMPS (curves 3 and 4,
respectively). When added at 600 µM, pCMPS completely
abolished glutamate generation by NMDA-damaged neurons exposed to cell
culture medium and glutamine (not shown).
Evidence for Involvement of the Glutaminase in Neurotoxicity
In addition to blocking the gradual increase in glutamine hydrolysis in neuronal cultures exposed to glutamine (Fig. 4, upper panel), 30 µM pCMPS also prevented the release of LDH that is caused by glutamine exposure (Fig. 4, lower panel). The neuroprotection by pCMPS in this protocol was verified by morphological assessment, which showed that neurons retained their normal appearance after 24 h in the presence of 30 µM pCMPS and 2 mM glutamine but were severely damaged if exposed to 2 mM glutamine alone (data not shown).
The neuroprotection observed with pCMPS, together with its inhibition of glutamate generation, strongly suggests that the glutaminase contributes directly to neuronal death in neuronal cultures exposed to glutamine. Problems with toxicity prevented a direct examination of the effects of DON and pCMPS in the standard model of hypoxic neuronal injury in mixed neuronal-glial cultures (26, 27). However, it was possible to investigate the relationship between extracellular glutamate concentrations, glutamine exposure, and neuronal death in mixed cultures exposed to combinations of hypoxia and glutamine. Data on glutamate and glutamine concentrations in the medium of mixed cultures exposed to combinations of glutamine and hypoxia are summarized in Table IV. Data on glial cultures are presented as a control to confirm the neuronal origin of increased glutamate production caused by combined glutamine and hypoxia.
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The exposure of mixed neuronal-glial cultures to the combination of
glutamine and hypoxia produced a medium glutamate concentration of 3 µM (Table IV), which was significantly greater than that produced by hypoxia alone (0.3 µM, Table IV) or glutamine
alone (0.8 µM, Table II) (p < 4 × 104 for both comparisons). This increase in medium
glutamate was associated with 42.2 ± 3.1% (n = 23) of total LDH release 24 h after the beginning of hypoxia, or
16% over that produced with hypoxia alone and 25% over that produced
by glutamine alone (p < 2.5 × 10
4
for both comparisons). Exposure to 500 µM NMDA for 5 h followed by 2 mM glutamine resulted in a glutamate
concentration of 7.0 ± 0.6 µM (n = 16) in the medium at 4 h after glutamine addition and 84 ± 12% (n = 24) of total LDH release at 24 h. Values
for LDH release were also measured immediately after hypoxia or NMDA treatment and were uniformly 60-70% of those measured at 24 h (data not shown). We conclude that increased glutamate production in
this model of hypoxic neuronal injury is proportional to the amount of
neuronal death and dependent on the presence of glutamine, properties
that implicate the glutaminase.
Consistent with previous reports (38, 39) hypoxia (5 h, n = 8 culture wells) and glutamine (2 mM, n = 4 culture wells) had no effect on the clearance of glutamate from mixed cultures (data not shown). These results indicate that altered uptake is not responsible for glutamine toxicity in hypoxic mixed cultures.
Glutaminase Activity Remains Localized in Cellular FragmentsThe above experiments measure glutamate production by
the glutaminase in tissue culture medium but do not address whether the
enzyme is released in a soluble form after cell death or whether it
remains associated with cellular fragments. Fig. 5
(upper panel) shows a comparison of the percentage of total
glutaminase and LDH activity either released into cell culture medium
or retained in the cellular layer after a 5-h exposure of neuronal
cultures to 500 µM NMDA. About 90% of the glutamine
hydrolysis activity remains associated with cellular fragments. A much
greater proportion of total neuronal LDH is released into the culture
medium at this time (50%). As with the total glutamine hydrolysis
activity (above), the fraction of glutamine hydrolysis activity found
in the culture medium after excitotoxic neuronal death had properties
of the mitochondrial glutaminase; the activity was particulate as shown by centrifugation, activated by phosphate, and inhibited by pCMPS (data
not shown).
Western blot analysis was used to further characterize the glutaminase after neuronal death. Neuronal cultures were treated for 5 h with control medium or with medium containing 500 µM NMDA. The resulting cell layers contain nearly equivalent amounts of anti-glutaminase immunoreactive peptide (Fig. 5, lower panel, lanes 2 and 3). The identified peptide has an apparent molecular mass (~63 kDa) that is slightly less than that of the 68- and 66-kDa peptides that constitute the rat brain glutaminase (19). These experiments independently confirm that the bulk of the mitochondrial glutaminase is retained in the cellular layer following neuronal death. However, a slight but significant amount of the anti-glutaminase immunoreactive peptide was recovered from the medium of cells treated with NMDA (Fig. 5, lower panel, lane 5). From densitometric tracings, the released peptide was approximately 3% of the total cellular glutaminase. No detectable immunoreactive peptide was recovered from the medium removed from control cells (lane 4). Finally, the immunoreactive glutaminase peptide recovered from all of the mouse cell samples exhibits the same electrophoretic mobility.
Neuronal death produces high rates of glutamine hydrolysis, which persist unchanged for at least 4 h. This prolonged generation of glutamate from glutamine by damaged neurons is at least 10-fold greater than glutamate generation by undamaged neuronal and glial cultures exposed to glutamine. Although measurable amounts of glutamate are released by neuronal death itself, this amount is equivalent to only 6-8 min of glutamine hydrolysis by damaged neurons in the presence of 2 mM glutamine.
The studies with inhibitors and activators strongly support the hypothesis that a single molecular entity, the mitochondrial glutaminase, is responsible for the great majority of glutamine hydrolysis following neuronal death: Although DON and pCMPS are not selective for the glutaminase, they work by different mechanisms, and it is unlikely that another brain enzyme that hydrolyzes glutamine to glutamate is inhibited by both. Furthermore, the requirement for polyvalent anions (such as phosphate) for activation is unique to the glutaminase (14, 19).
Western blotting, as well as measurement of glutaminase activity in cells and cell culture medium, shows that the glutaminase remains in cell fragments after a 5-h exposure to 500 µM NMDA. The observation that the electrophoretic mobility of the enzyme remains unchanged suggests that the glutaminase retained in NMDA-damaged cells is not degraded and is consistent with the continued activity of the enzyme after neuronal death. One possibility is that the association of the enzyme with the mitochondrial membrane (19) may protect it from degradation by proteases. Further study of enzyme stability and activity after neuronal death, particularly in in vivo models of stroke, will be useful in further evaluating the role of the enzyme in pathological glutamate production in vivo.
Although the glutaminase remains localized in cell fragments in the initial stages after excitotoxic cell death, it is accessible to inhibition by the membrane-impermeant inhibitor, pCMPS. Since pCMPS does not inhibit glutaminase activity in intact rat renal mitochondria (17), this is probably a direct effect on the enzyme as opposed to an indirect effect on membrane transport of glutamine. This result suggests that the active form of the glutaminase is not membrane-limited and that the net increase in glutamine hydrolysis that is observed after excitotoxic neuronal death is due to membrane breakdown. A consequence of this conclusion is that it should be possible to develop agents that, by virtue of their membrane transport/permeability properties, inhibit only pathological glutamate production by exposed glutaminase but do not inhibit normal glutaminase activity in intact mitochondria. Such agents would potentially block pathological glutamate production without interfering with normal glutamatergic transmission.
Concentrations of glutamate sufficient to cause toxicity (i.e., significantly above 1 µM; Refs. 21 and 27) were found in the medium of cultures where there is both neuronal damage and 2 mM added glutamine but were not found with undamaged cultures. The 3 µM concentration of glutamate that was observed in hypoxic mixed cultures exposed to glutamine is consistent with the IC50 for toxicity of glutamate observed in neuronal cultures (2-10 µM) and the increased amount of neuronal death observed in these cultures. The addition of 2 mM glutamine does not cause accumulation of concentrations of glutamate of over 1 µM in mixed cultures not subjected to added stress (Table II). Likewise, the combination of hypoxia and glutamine does not cause glutamate to exceed 0.5 µM in the medium of glial cultures. The 2 mM concentration of glutamine is similar to that found in brain (0.3-0.5 mM in cerebrospinal fluid and 2-4 mM in bulk nervous tissue; Refs. 11 and 40) and is probably relevant to ischemic injury in vivo.
The experiments on glutamine neurotoxicity suggest that the contribution of the glutaminase to neuronal damage depends strongly on the glial clearance of glutamate, which ultimately regulates the concentration of glutamate achieved at any given rate of generation. In the neuronal cultures, removal of medium glutamate is slow. Here, glutamine exposure eventually results in steadily increasing concentrations of glutamate and rates of glutamine hydrolysis, leading to complete neuronal death. In the mixed cultures, glial uptake maintains low concentrations of glutamate, even in the presence of 2 mM glutamine, and glutamine toxicity is observed only if combined with an additional stress, such as hypoxia.
In these experiments, glucose was present during hypoxia, and glial uptake of glutamate remained unchanged in hypoxic mixed cultures exposed to glutamine. However, glial uptake is reduced by hypoglycemia and acidosis in ischemia in vivo (38). Further studies are required to define precisely how decreased glial uptake will interact with glutamine hydrolysis by the glutaminase following neuronal damage in vivo. Selective inhibitors of the glutaminase should provide the most direct answers about the role of the glutaminase in neuronal injury in vivo and may prove to be clinically useful.
In summary, mechanical or excitotoxic neuronal death activates the prolonged hydrolysis of extracellular glutamine by the mitochondrial glutaminase. This elevated activity is a feature of damaged neurons, since intact neurons or glia exposed to glutamine did not generate glutamate at comparable rates. The neuroprotection observed with the membrane-impermeant pCMPS indicates that it may be possible to produce agents that selectively inhibit the elevated glutaminase activity by damaged neurons while leaving the activity of the glutaminase in undamaged cells relatively intact. Such an approach could be a useful complement or alternative to existing strategies aimed at producing neuroprotection following stroke and other disorders by blockade of the postsynaptic receptors for glutamate.
We thank Dan Hartline and Eng Lo for helpful comments regarding the manuscript and for the analysis of the experimental data, and we thank the members of the Neurex research committee for helpful suggestions.