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The Journal of Neuroscience, October 1, 1998, 18(19):7727-7738
Rapid Ca2+ Entry through Ca2+-Permeable
AMPA/Kainate Channels Triggers Marked Intracellular Ca2+
Rises and Consequent Oxygen Radical Production
Sean G.
Carriedo3,
Hong
Zhen
Yin1,
Stefano L.
Sensi1, and
John H.
Weiss1, 2, 3
Departments of 1 Neurology, 2 Anatomy and
Neurobiology, and 3 Psychobiology, University of
California, Irvine, Irvine, California 92697-4292
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ABSTRACT |
The widespread neuronal injury that results after brief activation
of highly Ca2+-permeable NMDA channels may, in large
part, reflect mitochondrial Ca2+ overload and the
consequent production of injurious oxygen radicals. In contrast,
AMPA/kainate receptor activation generally causes slower toxicity, and
most studies have not found evidence of comparable oxygen radical
production. Subsets of central neurons, composed mainly of GABAergic
inhibitory interneurons, express AMPA/kainate channels that are
directly permeable to Ca2+ ions. Microfluorometric
techniques were performed by using the oxidation-sensitive dye
hydroethidine (HEt) to determine whether the relatively rapid
Ca2+ flux through AMPA/kainate channels expressed on
GABAergic neurons results in oxygen radical production comparable to
that triggered by NMDA. Consistent with previous studies, NMDA
exposures triggered increases in fluorescence in most cultured cortical
neurons, whereas high K+ (50 mM)
exposures (causing depolarization-induced Ca2+
influx through voltage-sensitive Ca2+ channels)
caused little fluorescence change. In contrast, kainate exposure caused
fluorescence increases in a distinct subpopulation of neurons;
immunostaining for glutamate decarboxylase revealed the responding
neurons to constitute mainly the GABAergic population. The effect of
NMDA, kainate, and high K+ exposures on oxygen
radical production paralleled the effect of these exposures on
intracellular Ca2+ levels when they were monitored
with the low-affinity Ca2+-sensitive dye fura-2FF,
but not with the high-affinity dye fura-2. Inhibition of mitochondrial
electron transport with CN or rotenone almost
completely blocked kainate-triggered oxygen radical production.
Furthermore, antioxidants attenuated neuronal injury resulting from
brief exposures of NMDA or kainate. Thus, as with NMDA receptor
activation, rapid Ca2+ influx through
Ca2+-permeable AMPA/kainate channels also may
result in mitochondrial Ca2+ overload and consequent
injurious oxygen radical production.
Key words:
cell culture; glutamate; AMPA; kainate; NMDA, cobalt; hydroethidine; calcium imaging; fura-2; fura-2FF; free radicals; superoxide; tetramethylrhodamine ethylester
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INTRODUCTION |
Agonist-triggered
Ca2+ influx may constitute a key link between
glutamate receptor activation and subsequent neurodegeneration. In
cortical culture, brief periods of activation of NMDA channels, which
are highly Ca2+-permeable (MacDermott, 1986 ), are
capable of triggering widespread neurodegeneration. In contrast, much
more prolonged periods of activation of AMPA/kainate receptor-gated
channels are required before comparable neurotoxicity develops (Koh et
al., 1990; Choi, 1992). This may reflect the fact that most
AMPA/kainate channels are poorly permeable to Ca2+
and likely cause secondary Ca2+ influx via the
depolarization and activation of voltage-sensitive Ca2+ channels (VSCCs; Murphy and Miller, 1989; Weiss
et al., 1990a). Multiple factors have been hypothesized to contribute
to the differences in toxicity that result from NMDA and AMPA/kainate
receptor activation. First, observations that NMDA and kainate
exposures induce comparable elevations in intracellular
Ca2+
([Ca2+]i) (Tymianski et al.,
1993; Rajdev and Reynolds, 1994; Dugan et al., 1995) have led to the
hypothesis that excitotoxic injury is Ca2+
source-dependent (Tymianski et al., 1993), with NMDA receptors most
closely linked to injury-initiating machinery (Tymianski et al., 1993;
Rajdev and Reynolds, 1994). However, the observation that brief NMDA
exposures cause much more 45Ca2+ influx
than kainate exposures has lent support to an alternative (but not
exclusive) hypothesis that the amount of Ca2+ entry
is a critical determinant of neuronal injury (Hartley et al., 1993;
Eimerl and Schramm, 1994; Lu et al., 1996).
Oxygen radicals are likely mediators of neuronal injury resulting from
glutamate exposure (Coyle and Puttfarcken, 1993). Evidence is
particularly compelling in the case of NMDA receptor activation, which
triggers rapid oxygen radical production (Lafon-Cazal et al., 1993;
Dugan et al., 1995; Reynolds and Hastings, 1995; Bindokas et al., 1996)
and injury, against which antioxidants are partially protective (Monyer
et al., 1990; Chow et al., 1994). Mitochondria buffer the large amounts
of Ca2+ that accumulate intracellularly in response
to NMDA receptor activation (Werth and Thayer, 1994; White and
Reynolds, 1995, 1997; Wang and Thayer, 1996) and may be the primary
source of NMDA-triggered oxygen radical production (Dugan et al., 1995; Reynolds and Hastings, 1995; Bindokas et al., 1996). The role of oxygen
radicals in AMPA/kainate receptor-mediated injury is less clear.
Although oxygen radical scavengers and inhibitors of oxygen radical
production have been protective against kainate-induced excitotoxicity
(Dykens et al., 1987; Patel et al., 1996), most (Lafon-Cazal et al.,
1993; Dugan et al., 1995; Reynolds and Hastings, 1995) but not all
(Bindokas et al., 1996) studies that used spin-trapping agents or
oxidation-sensitive fluorescent dyes have failed to detect oxygen
radical production after kainate exposure.
The discovery of subpopulations of central neurons that express
Ca2+-permeable AMPA/kainate channels (Iino et al.,
1990) and are unusually vulnerable to AMPA/kainate receptor-mediated
injury (Brorson et al., 1994; Turetsky et al., 1994; Yin et al., 1994a)
provides an opportunity to evaluate injury mechanisms initiated by the activation of a distinct agonist-activated Ca2+
entry route. Recent electrophysiological and histological studies indicate that nearly all GABAergic forebrain neurons express
Ca2+-permeable AMPA/kainate channels (Bochet et al.,
1994; Jonas et al., 1994; Yin et al., 1994a) and suggest that GABAergic
neurons may be the primary population of central neurons expressing
large numbers of these channels. The purpose of this project was
twofold. We first sought to determine whether kainate activation of
Ca2+-permeable AMPA/kainate channels on GABAergic
cortical neurons can trigger acute oxygen radical production. Second,
we used Ca2+-sensitive fluorescent dyes to examine
the relationship between intracellular Ca2+ levels
achieved on the activation of different Ca2+ entry
routes (NMDA channels, Ca2+-permeable AMPA/kainate
channels, and VSCCs) and the resultant oxygen radical production.
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MATERIALS AND METHODS |
Chemicals and reagents. Hydroethidine (HEt),
tetramethylrhodamine ethylester (TMRE), and fura-2 were purchased from
Molecular Probes (Eugene, OR). Fura-2FF was purchased from Texas
Fluorescence Lab (Austin, TX). MK-801 was purchased from Research
Biochemicals (Natick, MA). Tissue culture media and serum were obtained
from Life Technologies (Grand Island, NY).
2,3-Dihydroxy-6-nitro-7-sulfamoyl-benzo(F)quinoxaline (NBQX) was kindly
provided by Novo Nordisk (Malov, Denmark). NMDA, kainate, rotenone,
cyanide, trolox, and carbonyl cyanide
p-(trifluoromethoxy)phenyl hydrazone (FCCP) were obtained
from Sigma (St. Louis, MO). U74500 was kindly provided by Upjohn
(Kalamazoo, MI). All other chemicals and reagents were obtained from
common commercial sources.
Cortical cultures. Cultures were prepared mainly as
described previously (Yin et al., 1994a). Briefly, dissociated mixed
neocortical cell suspensions were prepared from 14- to 16-d-old
embryonic Swiss-Webster mice and plated (1-2 × 105 cells/cm2) on a previously
established layer of cortical astrocytes. Initial plating medium
consisted of Eagle's Minimum Essential Medium (EMEM; Earle's salts
prepared glutamine-free) supplemented with 10% heat-inactivated horse
serum, 10% fetal bovine serum, 2 mM glutamine, and 25 mM glucose. Cultures were kept in a 37°C/5%
CO2 incubator. After 4-6 d in vitro
(DIV), non-neuronal cell division was halted by exposure to
105 cytosine arabinoside for 24 hr. Then the cells
were switched to an identical maintenance medium lacking fetal serum.
Subsequent media replacement occurred twice a week, and cells were
studied after 14-16 DIV.
The same procedure was used to prepare glial cultures, except that
tissue was obtained from early postnatal (1-3 d) mice, plating media
were supplemented with epidermal growth factor (10 ng/ml), and cell
suspensions were plated directly on Primaria tissue culture-treated
multiwell plates (Falcon, Franklin Lake, NJ) or
poly-L-lysine-coated glass.
Immunocytochemistry. GABAergic cortical neurons were labeled
with glutamic acid decarboxylase (GAD; Developmental Studies Hybridoma
Bank at the University of Iowa, Iowa City, IA) immunohistochemistry. Cultures were fixed for 40 min in 4% paraformaldehyde, washed three
times with PBS, and incubated for 30 min with "blocking solution" (10% horse serum in PBS) to minimize background staining. Primary antibody exposures (1:500) occurred for 72 hr at 4°C. Biotinylated horse anti-mouse (Vector Laboratories, Burlingame, CA),
ABC solution (Vector Laboratories), and 3-amino-9-ethyl-carbazole (AEC;
Sigma) were used to visualize stained cells.
Co2+ labeling. Co2+
labeling was performed generally as previously described (Pruss et al.,
1991) with minor modifications (Yin et al., 1994a). Cultures were
Co2+-loaded by exposure to kainate (100 µM) with Co2+ (2.5 mM) in
an uptake buffer [containing (in mM) 139 sucrose, 57.5 NaCl, 5 KCl, 2 MgCl2, 1 CaCl2, 12 glucose, and 10 HEPES, pH 7.6] for 15 min. Then the cultures were
washed in uptake buffer with 3 mM EDTA to remove
extracellular Co2+ and were incubated in 0.05%
(NH4)2S for 5 min to precipitate intracellular Co2+, followed by an uptake buffer
wash and fixation (4% paraformaldehyde for 40 min). For silver
enhancement the cultures were washed in development buffer [containing
(in mM) 292 sucrose, 15.5 hydroquinone, and 42 citric
acid] and incubated in 0.1% AgNO3 in development buffer
at 50-55°C. This solution was changed at 15 min intervals while
enhancement was monitored periodically via microscopic observation. When enhancement was complete (usually after 30 min), the reaction was
terminated by being washed three times in warm development buffer.
Neurotoxicity experiments. Toxic exposures to either NMDA
(100 µM + 10 µM NBQX for 10 min) or to
kainate (100 µM + 10 µM MK-801 for 20 min)
were performed in room air (25°C), using a HEPES-buffered salt
solution (HSS) with the following composition (in mM): 130 Na+, 5.4 K+, 0.8 Mg2+, 1.8 Ca2+, 130 Cl, 20 HEPES, pH 7.4 at 25°C, and 15 glucose.
Exposures were terminated by replacing the exposure solution with MEM
plus glucose along with 10 µM MK-801/10 µM
NBQX and returning the cultures to the incubator. To assess
neuroprotection from antioxidants (20 µM U74500 or 3 mM trolox), we exposed the cultures to the
antioxidant for 1 hr before and during and for 20-24 hr after the
toxic exposure. Overall neuronal injury was assessed 20-24 hr after
the start of the exposures by morphological examination and was
assessed quantitatively by measurement of lactate dehydrogenase (LDH)
in the bathing medium, an index proportional to the total number of
damaged neurons (Koh and Choi, 1987). LDH values are scaled to the
near-maximal mean value found in sister cultures exposed to 300 µM kainate for 24 hr (equal to 100% cell loss).
Kainate-induced damage to the GAD(+) subpopulation was assessed by
direct cell counts of intact GAD(+) neurons in kainate-exposed
cultures, in comparison to numbers present in sister cultures exposed
to sham wash alone.
Imaging studies. Cultures were plated on glass-bottomed
dishes (Mattek Cultureware, Ashland, MA) and mounted to a stage adapter on an inverted microscope (Nikon Diaphot, Tokyo, Japan). All agonist exposures were performed at room temperature (25°C) in a 1.5 ml static HSS bath. High K+ exposures were in identical
buffer except for the substitution of 50 mM
K+ for equimolar Na+. Preselected
fields were illuminated by a xenon light source and a Nikon 40×
magnification, 1.3 numerical aperture, epifluorescence oil immersion
objective. Emitted fluorescence was imaged with a Hamamatsu intensified
charge-coupled device camera (Hamamatsu City, Japan). In all
experiments the electronic background signals (obtained with the camera
shutter closed) were obtained at each wavelength for subtraction from
measured signals, and baseline fluorescence measurements were obtained
for 10 min before the addition of agonists. To analyze experiments, we
outlined neuronal somata and gathered data on an 80486-based computer,
using Image-1/Fluor software from Universal Imaging (West Chester,
PA).
For [Ca2+]i measurements the cultures
were loaded in the dark, with a 5 µM concentration of
either fura-2 AM or fura-2FF AM in HSS containing 0.2% pluronic acid
and 0.4% dimethyl sulfoxide (DMSO) for 30 min at 25°C. Then the
cultures were washed in HSS (three times) and kept in the dark for an
additional 30 min to allow for complete dye deesterification. Cells
were illuminated alternately at 340 and 380 nm, and fluorescence was
monitored at 510 nm. For fura-2,
[Ca2+]i levels were expressed as the
ratio of emitted fluorescence on excitation at 340 and 380 nm. For
fura-2FF, [Ca2+]i was determined by
the equation:
where R is the observed 340:380 fluorescence ratio
(Grynkiewicz et al., 1985). Rmin is the 340:380
fluorescence ratio value determined in cortical neurons exposed to
Ca2+-free HSS in the presence of a 2 mM
concentration of the Ca2+ chelator EGTA and a 10 µM concentration of the Ca2+ ionophore
ionomycin. Rmax is the 340:380 fluorescence
ratio value determined in the same neurons exposed to ionomycin in the
presence of 10 mM Ca2+.
Fmin indicates 380 nm fluorescence at
Rmin, and Fmax
indicates 380 nm fluorescence at Rmax. For
Fura-2FF, the KD used was 35 µM
(Golovina and Blaustein, 1997). The system was recalibrated after any
adjustments to the apparatus. Oxygen radical production was monitored
with the oxidation-sensitive dye HEt. Stock HEt (1 mg/ml) was prepared
as previously described (Bindokas et al., 1996) in dry DMSO and stored
in frozen aliquots for use within 8 weeks. Cultures were loaded in the
dark with 5 µM HEt in HSS (for 45 min at 25°C), and the
same concentration of HEt was maintained in the bath throughout each
experiment. To minimize dye photo oxidation, we decreased light
illumination to 2.5% of initial output, using UV grade neutral density
filters (Omega Optical, Brattleboro, VT) and images (16 frame samples)
obtained at 1-2 min intervals. Under these conditions, little
fluorescence increase occurred within 50 min (see Fig. 3). Cells were
excited at 510-560 nm, and emission was monitored at >590 nm. Camera
gain was adjusted to give baseline maximal fluorescence levels of
40-60 (arbitrary units) of a maximal eight-bit signal output of 256. Fluorescence measurements for each cell
(Fx) were normalized to the average fluorescence intensity for that cell during the 10 min baseline period
(F0). Because fluorescence is cumulative,
oxygen radical production rate was assessed as the rate of increase (or
slope) of the
Fx/F0 curves over
time, and net oxygen radical production was assessed as the increase in
Fx/F0 over
baseline. Control experiments using 1 µM HEt were
performed exactly as those above (using 5 µM HEt),
except for the concentration of HEt in the bath.
For dual imaging of oxygen radicals and
[Ca2+]i, cultures were loaded
first with fura-2FF as described. During the deesterification of the
fura-2FF, cultures were loaded with HEt as described. For data
acquisition the fura-2FF images were obtained immediately before HEt
images, each with appropriate excitation and emission filters, at 2 min
intervals. Data were analyzed separately, including separate background
subtractions, for each dye as described. Control experiments, which
used excitation and emission settings for one dye in the presence of
the other dye only, revealed no cross fluorescence.
For assessment of changes in mitochondrial potential (  ), neurons
were incubated for 30 min with TMRE (0.1 µM) at 37°C,
and the same concentration of TMRE was maintained in all bathing
solutions throughout the experiments (performed at 25°C; Farkas et
al., 1989). Cells were excited at 495 nm, emission was monitored
at  530 nm, and images were acquired every 60 sec. To avoid
photobleaching, we attenuated the fluorescence intensity with neutral
density filters (Omega Optical). Camera gain was adjusted to give
baseline maximal fluorescence levels of 150-200 (arbitrary units) of a maximal eight-bit signal output of 256. Fluorescence changes were quantified by selecting a cytoplasmic region of each cell that was
strongly fluorescent at baseline (indicating that it was
"mitochondria-rich") and normalizing subsequent fluorescence
measurements to the baseline fluorescence
(F0), which was assessed as the emitted
fluorescence of the initial image taken during the experiment.
For experiments involving cyanide (CN; 3 mM), cultures were preexposed to CN
for 15 min before the addition of agonists. For rotenone, cultures were
preexposed (10 µM) for a 40 min period that ran
concurrently with HEt or TMRE loading. For experiments involving
CN or rotenone, glutamate antagonists (10 µM NBQX or 10 µM MK-801) were added as
appropriate both before and during agonist exposures to minimize the
effects attributable to endogenous glutamate release and to isolate
measured effects to the desired channel type.
Experiment replication. All reported experiments represent
at least three independent replications. All imaging studies represent at least 15 GAD(+) neurons and 100 GAD( ) cortical neurons.
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RESULTS |
Kainate-triggered oxygen radical production is dependent on
extracellular Ca2+
Neurons possessing Ca2+-permeable AMPA/kainate
channels (Iino et al., 1990) can be identified by a histochemical
technique that is based on kainate-triggered uptake of
Co2+ ions [Co2+(+) neurons;
Pruss et al., 1991]. The specificity of this stain is indicated by the
inability of NMDA or high K+ to substitute for
kainate in triggering Co2+ ion entry. Consistent
with electrophysiological studies (Bochet et al., 1994; Jonas et al.,
1994), we have reported previously that nearly all (90%) of GABAergic
cortical neurons are Co2+(+) (Yin et al., 1994a)
(Fig. 1). We have chosen to focus the present studies of effects of Ca2+ entry through
Ca2+-permeable AMPA/kainate channels on the
GABAergic population for two reasons. First, whereas the overall
Co2+(+) population contains heterogeneous neuronal
cell types, the GABAergic population [identified via glutamic acid
decarboxylase immunohistochemistry; GAD(+) neurons] constitutes a well
defined and physiologically important subset of cortical neurons. In
addition, because Co2+ labeling depends on the
normal functioning of AMPA/kainate channels, labeling after toxic
agonist exposures may fail in a portion of the neurons with
Ca2+-permeable AMPA/kainate channels.
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Figure 1.
Glutamic acid decarboxylase (GAD)-immunoreactive
cortical neurons exhibit kainate-stimulated Co2+
uptake. Cultures were subjected to kainate-stimulated
Co2+ loading (see Materials and Methods), followed
by processing for GAD immunocytochemistry. Then selected immunostained
fields were photographed (400× magnification) before
(A) and again after (B)
development of the Co2+ stain.
Co2+(+) neurons can be identified by a
darkening in the cell body and processes. Scale bar,
50 µm.
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Because both Ca2+-permeable AMPA/kainate and NMDA
channels may permit rapid Ca2+ influx (Lu et al.,
1996), we sought first to determine whether the activation of
Ca2+-permeable AMPA/kainate channels can cause
oxygen radical production similar to that observed on NMDA receptor
activation (Lafon-Cazal et al., 1993; Dugan et al., 1995; Reynolds and
Hastings, 1995; Bindokas et al., 1996). Intracellular oxygen radical
production was monitored by measuring changes in the fluorescence of
cells loaded with HEt, a dye that readily permeates living cells and is
reported to be oxidized selectively by superoxide radicals into a
highly fluorescent compound, ethidium (Bindokas et al., 1996; Satoh et
al., 1998). HEt has certain advantages over other frequently used
oxidation-sensitive dyes for the present purposes. Dihydrorhodamine
gives a speckled signal of mitochondrial origin that is best
appreciated under high-power confocal microscopy (Dugan et al., 1995)
and is poorly suited for comparing responses in large fields of
neurons. Dichlorofluorescein fluorescence is potently blocked by
intracellular acidification (Reynolds and Hastings, 1995) and is thus
not suitable, because agonist-triggered intracellular acidification is
highly dependent on the influx of extracellular Ca2+
(Irwin et al., 1994) and may differ markedly between cells expressing large numbers of Ca2+-permeable AMPA/kainate
channels (which permit rapid Ca2+ influx) and cells
lacking these channels. An advantage of HEt is that ethidium
intercalates within nuclear DNA where the fluorescence intensity of the
dye increases greatly (LePecq and Paoletti, 1967), providing high
sensitivity. Also, the relative resistance of HEt to auto-oxidation and
photo-oxidation (in comparison to other oxidation-sensitive fluorescent
dyes) (Dugan et al., 1995; Reynolds and Hastings, 1995) permits the
prolonged periods of fluorescence monitoring needed for the present
studies (see Materials and Methods). Because the oxidized dye
accumulates within the cell, the oxygen radical production rate was
assessed as the rate of fluorescence increase over time, and net oxygen
radical production was assessed as the increase in fluorescence over
baseline. To compare oxygen radical production across experiments, we
normalized all fluorescence readings for a given cell
(Fx) to the average fluorescence that was
seen in the 10 min baseline period (F0)
for that cell.
In cultures loaded with HEt (see Materials and Methods), a low rate of
basal oxygen radical production was evidenced by stable, slow increases
in fluorescence in neurons, but not in the underlying glia (see Fig.
3A). Baseline fluorescence readings were acquired for 10 min
before the addition of NMDA (200 µM + 10 µM
NBQX), kainate (200 µM + 10 µM MK-801), or
high K+ (50 mM + 10 µM
NBQX/MK-801) for an additional 20 min. On exposure to NMDA, noticeable
increases in fluorescence were seen within 2 min, with the majority of
neurons showing substantial increases in fluorescence (normalized
fluorescence increase of 1.23 ± 0.14 over baseline) by the end of
the 20 min exposure (Figs.
2,
3B). In contrast, on exposure
to high K+ (50 mM; a concentration
sufficient to cause significant neuronal depolarization) the
fluorescent increases (0.4 ± 0.01) were not significantly greater
than those observed in cultures exposed to buffer alone (0.23 ± 0.1) (Figs. 2, 3A). Kainate exposures produced more
selective increases in fluorescence. Consistent with previous studies
(Dugan et al., 1995; Reynolds and Hastings, 1995), kainate exposure had
little effect on the rate of oxygen radical production in the majority
of cortical neurons (0.29 ± 0.03). However, a subset of cortical
neurons, consisting predominantly of the GAD(+) neuronal population,
showed rapid fluorescence increases (1.68 ± 0.17) similar to
those seen with NMDA (Figs. 2, 3C). As expected, we found
that kainate triggered a similar selective increase (1.28 ± 0.07)
in fluorescence in the overall Co2+(+) neuronal
population (Fig. 3D).
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Figure 2.
NMDA, kainate, and high K+
exposures produce distinct patterns of oxygen radical generation.
Cortical cultures were exposed to NMDA (200 µM + 10 µM NBQX) (A), kainate (200 µM + 10 µM MK-801)
(B), or high K+ (50 mM + 10 µM MK-801/NBQX)
(C). In each experiment the images were obtained
under visible light before exposure (column 1), under
fluorescence for oxidized hydroethidine (HEt; see
Materials and Methods) 10 min before (column 2) and 20 min after (column 3) drug application, and again after
immunostaining for GAD (column 4). Note the
widespread fluorescence increases after NMDA exposure and the
relatively selective increases in GAD(+) neurons after kainate
exposure. As indicated by the pseudocolor scale bar, HEt
images represent fluorescent intensity on an eight-bit/0-256 scale.
Scale bar, 50 µm.
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Figure 3.
Time course of oxygen radical generation after
high K+, NMDA, and kainate exposures. HEt-loaded
cultures were imaged for 10 min before and 20 min after drug
application. For each cell the HEt fluorescence at each time point
(Fx) was normalized to the mean
fluorescence for that cell during the 10 min baseline period
(F0). Cultures were exposed to either
normal HSS alone or high K+ modified HSS (+ 10 µM MK-801/NBQX) (A), to NMDA (200 µM + 10 µM NBQX) (B),
or to kainate (200 µM + 10 µM MK-801)
(C, D). Immediately after imaging the cultures were
processed for GAD immunocytochemistry (A-C) or
for kainate-stimulated Co2+ labeling
(D). All traces represent the means ± SEM
of 15-30 GAD(+)/Co2+(+) and 100-200
GAD()/Co2+() neurons, derived from at least four
experiments.
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To examine the role of extracellular Ca2+ in
kainate-triggered oxygen radical production in GAD(+) neurons, we
exposed cultures to kainate (200 µM + 10 µM
MK-801) in consecutive extracellular Ca2+
concentrations of 0, 1.8, and 10 mM (Fig.
4). Kainate exposures in the absence of
extracellular Ca2+ failed to trigger significant
increases in fluorescence. Almost immediately on the return of
extracellular Ca2+ to physiological levels, rapid
increases in fluorescence were observed in GAD(+) neurons, but not in
GAD() neurons. Only when extracellular Ca2+ levels
were raised to 10 mM did the GAD() neurons begin to show fluorescence increases.
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Figure 4.
Kainate-triggered oxygen radical production is
Ca2+-dependent. After a 20 min baseline recording
the HEt-loaded cultures were exposed to kainate (200 µM + 10 µM MK-801) in the presence of the indicated
extracellular Ca2+ concentration. The traces
represent the means ± SEM of >30 GAD(+) and 100 GAD() neurons
from four experiments.
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Relationship between agonist-triggered oxygen radical production
and intracellular Ca2+ elevations
To assess more directly the role of Ca2+ influx
via different routes in oxygen radical production, we set out in
subsequent experiments to measure intracellular free
Ca2+ levels
([Ca2+]i) in GAD(+) and GAD()
neurons on exposures to NMDA, kainate, or high K+.
Initial experiments used the high-affinity ratiometric
Ca2+-sensitive dye fura-2 (KD
~224 nM). After loading cells with the dye and
establishing the 10 min baseline recording (see Materials and Methods),
we exposed the cultures to NMDA (200 µM + 10 µM NBQX), kainate (200 µM + 10 µM MK-801), or high K+ (50 mM + 10 µM NBQX/MK-801) for 15 min.
Immediately after the addition of each of these exposure solutions,
sharp increases in [Ca2+]i were seen
in both GAD(+) (Fig. 5A) and
GAD() neurons (Fig. 5C). Consistent with previous studies
that used this dye (Tymianski et al., 1993; Rajdev and Reynolds, 1994;
Dugan et al., 1995), measured [Ca2+]i
rises on each of these exposures were similar.
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Figure 5.
Measured [Ca2+]i
rises induced by exposure to NMDA, kainate, or high
K+ vary markedly, depending on the affinity of the
fluorescent Ca2+ indicator that was used. Cultures
were loaded with either fura-2 (A, C) or
fura-2FF (B, D), as described (see
Materials and Methods). Fura-2 [Ca2+]i
levels were expressed as fluorescence ratios, whereas fura-2FF
[Ca2+]i levels were expressed as
calibrated values. After baseline imaging the cultures were exposed for
15 min (starting at time 0) to NMDA (200 µM + 10 µM NBQX), kainate (200 µM + 10 µM MK-801), or high
K+ (50 mM + 10 µM
MK-801/NBQX), as indicated, and were processed for GAD
immunocytochemistry. Traces show the means ± SEM of
[Ca2+]i responses in GAD(+)
(A, B) and in GAD() neurons
(C, D) [15-25 GAD(+) neurons and >150
GAD() neurons in three experiments].
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Because fura-2 has been reported as underestimating maximal
agonist-triggered [Ca2+]i elevations
(Regehr and Tank, 1992; Petrozzino et al., 1995; Hyrc et al., 1997),
the above experiments were repeated by using a low-affinity
Ca2+-sensitive dye. Because mag-fura-5 has some
sensitivity to [Mg2+]i that could
interfere with the accuracy of calibrated measurements and the AM ester
of the Mg2+-insensitive Ca2+ dye,
benzothiazole coumarin (BTC), loads poorly (Hyrc et al., 1997), we
chose to use a newly available ratiometric dye, fura-2FF (KD ~35 µM) (Golovina and
Blaustein, 1997), which has similar spectral properties to fura-2 and
is completely insensitive to Mg2+. Unlike fura-2,
fura-2FF showed distinct differences in the
[Ca2+]i elevations triggered by NMDA,
kainate, and high K+ exposures (Fig.
5B,D). Although NMDA triggered large and persistent increases in [Ca2+]i levels in all
neurons, high K+ exposures produced a sharp but
transient increase in [Ca2+]i levels,
which returned to basal levels within 5 min. As in the case of oxygen
radical production, the effects of kainate on
[Ca2+]i levels differed markedly
between GAD(+) and GAD() neurons, with the former population showing
a sharp and persistent increase in
[Ca2+]i (Fig. 5B), whereas
[Ca2+]i rises seen in GAD() neurons
(Fig. 5D) were similar to those seen during high
K+ exposures. The direct relationship between
[Ca2+]i levels and HEt fluorescence is
illustrated further by simultaneous double imaging with fura-2FF and
HEt; neurons with the greatest increases in HEt fluorescence also
showed the highest [Ca2+]i responses
on activation of either NMDA or AMPA/kainate receptors (see Fig.
6A,B). Qualitatively similar results were obtained by using mag-fura-5 (data not shown).
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Figure 6.
NMDA- or kainate-triggered
[Ca2+]i elevations that were assessed
by fura-2FF predict oxygen radical production. Part A,
Pseudocolor images, Cultures were loaded with both
fura-2FF and HEt, and visible light images were obtained (A,
A'). Fluorescent fura-2FF (B, C and B',
C'), and HEt (E, F and E', F')
images were obtained 10 min before (B, B' and E,
E') and 15 min after (C, C' and F,
F') exposure to NMDA (200 µM + 10 µM NBQX) (top) or kainate (200 µM + 10 µM MK-801) (bottom).
Then the cultures were immunostained for GAD (D, D').
Note that, although NMDA triggers strong HEt and fura-2FF fluorescence
increases in nearly all neurons, with kainate exposures the
fluorescence of both dyes was increased selectively in the GAD(+)
neurons. As indicated by the scale bars, fura-2FF images represent
fluorescence ratios, and HEt images represent fluorescent intensity on
an eight-bit/0-256 scale. Scale bar, 50 µm. Part B,
Time course, Cultures were loaded with both fura-2FF and
HEt as above. After baseline imaging the cultures were exposed to
kainate (200 µM + 10 µM MK-801), and
changes in [Ca2+]i levels (left
axis, red lines) and oxygen radical production
(right axis, blue lines) were monitored
for an additional 15 min (see Materials and Methods). Traces show the
means ± SEM of 7 GAD(+) and 25 GAD() neurons from one
experiment, which is representative of three.
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Mitochondria are a major source of agonist-triggered oxygen
radical production
Because previous studies have found that mitochondria appear to be
a significant source of NMDA-triggered oxygen radical production (Dugan
et al., 1995; Reynolds and Hastings, 1995; Bindokas et al., 1996),
subsequent experiments used the mitochondrial electron transport
inhibitors cyanide (CN; 3 mM) and
rotenone (10 µM) to examine the role of mitochondria in
oxygen radical production in our culture system. In initial experiments
the HEt-loaded cultures were exposed to 3 mM
CN for 15 min (which caused a variable slight
increase in the rate of basal fluorescence change), followed by the
addition of NMDA (200 µM + 10 µM NBQX) or
kainate (200 µM + 10 µM MK-801) in the continuing presence of CN. NMDA exposures caused
only a brief increase in fluorescence in the presence of
CN in comparison to the much greater fluorescence
increase triggered in sister cultures identically exposed in the
absence of CN (Fig.
7A). Kainate-triggered
fluorescence increases in GAD(+) neurons were eliminated almost
completely by CN preexposure (Fig. 7B).
To control for possible nonspecific effects of high concentrations of
CN, we examined in further experiments whether
rotenone, which has been shown previously to block NMDA
receptor-mediated mitochondrial oxygen radical production (Dugan et
al., 1995), also could block kainate-triggered oxygen radical
production. As with CN, cultures exposed to
rotenone for 40 min before and during exposure to kainate (200 µM + 10 µM MK-801) showed almost complete
inhibition of oxygen radical production (Fig. 7C).
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Figure 7.
Electron transport inhibitors attenuate NMDA- or
kainate-triggered oxygen radical production. After baseline recordings
the cultures were exposed to 3 mM CN
for 15 min before NMDA (200 µM + 10 µM
NBQX) (A) or kainate (200 µM + 10 µM MK-801) (B) was added in the
continuing presence of CN (solid
traces). For a comparison of agonist effects between
CN-treated and normal conditions, fluorescence
intensities for each neuron were normalized to its average fluorescence
during the 10 min immediately before agonist addition. Other HEt-loaded
cultures were preexposed to rotenone (10 µM) for 40 min
before kainate (200 µM + 10 µM MK-801) was
added in the continued presence of rotenone (solid
traces, C). For the purposes of comparison, in
each experiment the sister cultures were exposed identically in the
absence of the electron transport inhibitor (broken
traces). Note that, because kainate caused little oxygen
radical production in GAD() neurons, B and
C illustrate the effect of electron transport inhibitors
on kainate-triggered oxygen radical production only on GAD(+)
neurons.
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Studies of NMDA receptor-mediated excitotoxicity have demonstrated the
occurrence of rapid Ca2+-dependent loss of
mitochondrial membrane potential (), which may be integral to the
disruption of mitochondrial functioning (Schinder et al., 1996; White
and Reynolds, 1996). Such loss of also may occur in the case of
rapid Ca2+ influx through
Ca2+-permeable AMPA/kainate channels. Thus, the
recent report by Budd et al. (1997), suggesting that loss of per
se (triggered by the addition of the protonophore FCCP) might
cause the voltage-dependent release of oxidized ethidium from
mitochondria, compels control studies to examine the degree to which
observed kainate-triggered HEt signals reflect oxygen radical
production. Initial control studies examined HEt signal in cultures
loaded with only 1 µM HEt, a concentration at which Budd
et al. (1997) found ethidium to remain bound within mitochondrial DNA
on FCCP-triggered loss of . Indeed, consistent with their
findings, no FCCP-triggered HEt signal was seen under these conditions
(data not shown). However, on exposure to kainate, increases in HEt
fluorescence were seen in GAD(+) neurons that were significantly
greater than those seen in GAD() neurons [normalized increase of
0.49 ± 0.06 in GAD(+) neurons vs 0.11 ± 0.01 in GAD()
neurons; n 50 cells from three experiments].
Although these absolute fluorescence increases were less than those
seen when 5 µM HEt was used, the relative increases were
similar, in both cases being approximately five to six times greater in
GAD(+) neurons than in GAD() neurons [with 5 µM HEt, the increase was 1.68 ± 0.17 in GAD(+) neurons vs 0.29 ± 0.03 in GAD() neurons].
Further experiments used the potential-sensitive dye TMRE to examine
the effects of NMDA and kainate exposures on in our system. This
dye rapidly equilibrates between cellular compartments as a function of
potential differences; the rapid loss of fluorescence from cellular
domains rich in mitochondria is indicative of the loss of
(Farkas et al., 1989). After the cultures were loaded with TMRE,
baseline fluorescence readings were acquired for 10 min before the
addition of NMDA (200 µM + 10 µM NBQX) or
kainate (200 µM + 10 µM MK-801) for an
additional 20 min. On the addition of NMDA a rapid and sharp increase
in fluorescence was seen (possibly reflecting an increase in
relative to the depolarized cytosol) (Farkas et al., 1989), followed by
a rapid loss of fluorescence in virtually all neurons (Fig.
8A), which reflects
redistribution of the dye from depolarized mitochondria (Farkas et al.,
1989; Schinder et al., 1996). On kainate exposure, an increase in
fluorescence was seen in most neurons that was similar to (but somewhat
smaller than) that seen with NMDA. However, although most neurons
showed a slow decline in fluorescence toward baseline levels, the
GAD(+) neuronal population showed a much more pronounced decrease in fluorescence (although still somewhat less than that seen with NMDA
exposures; Fig. 8B). Indeed, this comparison between
GAD(+) and GAD() neurons provides a useful internal control
indicating that the rapid fall in signal is attributable to the loss of
and not simply to cytosolic depolarization, because kainate
certainly triggers effective Na+-dependent neuronal
depolarization in virtually all neurons.
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Figure 8.
Kainate causes mitochondrial depolarization in
GAD(+) neurons, but not in GAD() neurons. Cultures were loaded with
0.1 µM TMRE for 30 min (see Materials and Methods). After
baseline recordings (F0) the cultures
were exposed to NMDA (200 µM + 10 µM NBQX;
A), to kainate (200 µM + 10 µM MK-801; B), or to kainate (200 µM + 10 µM MK-801) in the presence of
rotenone (10 µM; C) (see Materials and
Methods); the fluorescence was monitored for 20 min more. Traces show
the means ± SEM of TMRE fluorescence in all neurons
(A) or in GAD(+) neurons (B, C, solid
traces) and in GAD() neurons (B, C, broken
traces) [30-70 GAD(+) neurons and >150 GAD() neurons, more
than or equal to three experiments].
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To address further the concern that the kainate-triggered HEt signal
could partially reflect the loss of , we next examined the
effects of rotenone (10 µM) on kainate-triggered changes
in TMRE fluorescence. In cultures that were exposed to rotenone for 40 min before and during exposure to kainate (200 µM + 10 µM MK-801), changes in in GAD(+) neurons (assessed
as the fall in TMRE fluorescence) were indistinguishable from those
seen in the absence of rotenone (Fig. 8C). Thus, because
rotenone blocks the kainate-triggered HEt signal in GAD(+) neurons
without affecting kainate-induced changes in , the HEt signal
blocked by rotenone most likely reflects oxygen radical production.
Oxygen radicals contribute to NMDA or kainate receptor-mediated
injury to cortical neurons
Although the above experiments demonstrate that the NMDA or
kainate exposures do trigger oxygen radical production, the relevance of this oxygen radical production to resultant neurotoxicity was examined by using two antioxidants: U74500 (a 21 amino steroid; Monyer
et al., 1990) and trolox (a soluble vitamin E derivative; Chow et al.,
1994; Ciani et al., 1996). Toxic exposures were calibrated to trigger
~75% injury either to the entire neuronal population (100 µM NMDA; 10 min) or to only the GAD(+) neuronal
population (100 µM kainate; 20 min). To assess protection
by anti-oxidants, we added either 20 µM U74500 or 3 mM trolox to the culture media for 1 hr before and during
and for the 20-24 hr period after the toxic agonist exposure until
injury was assessed the next day (see Materials and Methods). Both
antioxidants significantly attenuated overall neuronal injury resulting
from NMDA exposures and the selective GAD(+) neuronal loss resulting
from kainate exposures (Fig. 9).
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Figure 9.
Antioxidants are neuroprotective against NMDA- or
kainate-induced neuronal injury. Cultures were exposed to kainate (100 µM for 20 min) or NMDA (100 µM for 10 min)
in the presence or absence of an antioxidant (3 mM trolox
or 20 µM U74500; see Materials and Methods), and injury
to the overall neuronal population (open bars) and to
the GAD(+) neuronal population (filled bars) was
assessed the next day. Values represent the means ± SEM compiled
from at least four experiments; n = 12-20 cultures
per condition. An ampersand indicates neuronal loss
significantly different from that caused by agonist alone; an
asterisk indicates GAD(+) neuronal loss significantly
different from total neuronal loss (p < 0.01 by two-tailed t test).
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| |
DISCUSSION |
The present study attempts to compare
[Ca2+]i responses, oxygen radical
production, and resultant neurotoxicity after the activation of the
three primary routes of Ca2+ entry: NMDA channels,
Ca2+-permeable AMPA/kainate channels, and VSCCs.
Using the oxidation-sensitive fluorescent dye HEt, we find that NMDA
exposures, but not high K+-induced neuronal
depolarization, caused increased signal in most cortical neurons.
Kainate exposures caused selective Ca2+-dependent
signal increases in GABAergic neurons, a subpopulation of cortical
neurons known to express large numbers of
Ca2+-permeable AMPA/kainate channels. The HEt signal
correlated with agonist-triggered elevations in
[Ca2+]i and was attenuated by the
inhibition of mitochondrial electron transport, suggesting a
mitochondrial origin. Control experiments showing that electron
transport inhibitors blocked kainate-triggered HEt signal without
affecting kainate-triggered loss of provide strong evidence that
the kainate-triggered HEt signal in GAD(+) neurons reflects oxygen
radical generation. Indicating that the oxygen radicals contribute to
neurodegeneration, antioxidants decreased injury resulting from toxic
kainate and NMDA exposures.
Relationship between intracellular Ca2+
and neurodegeneration
Although excitotoxic injury is dependent on extracellular
Ca2+, the relationship between agonist-induced
Ca2+ load and neuronal injury has been in question.
As discussed in the introductory remarks, the lack of a clear
relationship between agonist-induced
[Ca2+]i elevations and neuronal
survival (Michaels and Rothman, 1990; Dubinsky and Rothman, 1991;
Randall and Thayer, 1992; Dubinsky, 1993; Tymianski et al., 1993; Dugan
et al., 1995) led to the proposal that the specific route of
Ca2+ entry may be a critical determinant of neuronal
injury ("source specificity hypothesis"; Tymianski et al., 1993),
whereas the strong correlation between rapid NMDA-triggered
45Ca2+ influx and subsequent
neurodegeneration (Hartley et al., 1993; Eimerl and Schramm, 1994) lent
support to the alternative hypothesis that net intracellular
Ca2+ accumulation is critical
("Ca2+ load hypothesis"). The characterization
of neurons expressing large numbers of
Ca2+-permeable AMPA/kainate channels (Iino et al.,
1990; Brorson et al., 1992; Turetsky et al., 1994) provides new
opportunity to examine the relationship between agonist-induced
Ca2+ entry and neuronal injury. Indeed, we can now
compare the effects of Ca2+ entry through NMDA and
Ca2+-permeable AMPA/kainate channels (which likely
share similar dendritic localization; Bekkers and Stevens, 1989; Gu et
al., 1996) and Ca2+ entry through VSCCs and
Ca2+-permeable AMPA/kainate channels (both of which
are activated by AMPA/kainate receptor stimulation but differ markedly
in cellular distribution).
Recent studies have provided some support for the
Ca2+ load hypothesis. First, despite the lack of a
clear difference in fura-2-measured [Ca2+]i responses on the activation of
the three routes of Ca2+ entry, we recently found,
using 45Ca2+ accumulation measurements,
that Ca2+-permeable AMPA/kainate channels appeared
to permit high rates of Ca2+ influx (comparable to
those triggered by NMDA). Furthermore, the estimated
Ca2+ influx rate on the activation of any of the
Ca2+ entry routes generally predicted the degree of
resultant injury (Lu et al., 1996). Also, a recent study that used a
low-affinity Ca2+-sensitive dye found NMDA-triggered
[Ca2+]i responses to be much greater
than those to kainate (Hyrc et al., 1997), suggesting that the lack of
relationship between [Ca2+]i and
injury seen in previous studies (Michaels and Rothman, 1990; Dubinsky
and Rothman, 1991; Randall and Thayer, 1992; Dubinsky, 1993; Tymianski
et al., 1993; Dugan et al., 1995; Lu et al., 1996) might reflect
technical limitations of the measurements. Specifically, high-affinity
dyes like fura-2 and indo-1 may be unable to resolve micromolar
Ca2+ responses accurately (Tsien, 1988; Petrozzino
et al., 1995; Hyrc et al., 1997) and at high concentrations actually
may buffer intracellular Ca2+ (Regehr and Tank,
1992; Tatsumi and Katayama, 1994; Petrozzino et al., 1995). The present
observation that the low-affinity dye fura-2FF, but not fura-2,
distinguishes kainate-triggered
[Ca2+]i responses in GABAergic neurons
from those in other neurons extends the findings of Hyrc et al. (1997)
by suggesting that, as with NMDA, the activation of
Ca2+-permeable AMPA/kainate channels can cause high
[Ca2+]i responses that predict high
toxicity.
Oxygen radical production in excitotoxic injury: relationship to
Ca2+ load
To compare NMDA and Ca2+-permeable AMPA/kainate
receptor-mediated injury mechanisms, we find that it is necessary to
examine not only [Ca2+]i responses but
also the processes downstream from Ca2+ entry that
may contribute to the injury. Imaging and toxicity studies have
provided considerable evidence that Ca2+-dependent
oxygen radical production contributes critically to NMDA
receptor-mediated injury (Monyer et al., 1990; Lafon-Cazal et al.,
1993; Chow et al., 1994; Dugan et al., 1995; Reynolds and Hastings,
1995). However, the finding of most previous studies (Lafon-Cazal et
al., 1993; Dugan et al., 1995; Reynolds and Hastings, 1995) that
AMPA/kainate receptor activation failed to trigger evident oxygen
radical production lent support to the source specificity hypothesis by
suggesting that NMDA and AMPA/kainate receptor-mediated neurotoxicities
are fundamentally different (Tymianski et al., 1993; Rajdev and
Reynolds, 1994). In contrast to the present study, a previous study
failed to find evidence of kainate-triggered oxygen radical production
in cortical neurons, even those expressing Ca2+-permeable AMPA/kainate channels (Canzoniero et
al., 1994). Possible differences include the use of dihydrorhodamine
from the previous study, which may be less sensitive to oxygen radical
production than HEt, and their coloading with fura-2 (to preidentify
neurons with Ca2+-permeable AMPA/kainate channels),
which could have buffered and limited the availability of
[Ca2+]i (Regehr and Tank, 1992;
Tatsumi and Katayama, 1994; Petrozzino et al., 1995). Indeed, a study
that used HEt did report kainate to trigger oxygen radical production
in certain hippocampal neurons but did not characterize the responding
neuronal population (Bindokas et al., 1996).
Present findings that kainate exposures can trigger rapid and
relatively selective oxygen radical production in GABAergic neurons and
that oxygen radical scavengers attenuate the resultant injury provide
strong evidence that rapid Ca2+ flux through
Ca2+-permeable AMPA/kainate channels is capable of
causing injurious oxygen radical production. Thus, present data lend
support to the Ca2+ load hypothesis by suggesting
that similar mechanisms underlie NMDA receptor-mediated injury and the
selective injury triggered by strong activation of
Ca2+-permeable AMPA/kainate channels. The importance
of Ca2+ load, however, need not exclude the
importance of Ca2+ source effects. Of note,
Ca2+-permeable AMPA/kainate channels and NMDA
channels likely are concentrated in postsynaptic regions of dendrites
(Bekkers and Stevens, 1989; Perkel et al., 1993; Malinow et al., 1994;
Murphy et al., 1994; Gu et al., 1996). Ca2+ entering
through either of these channels often may be constrained spatially and
thus could cause similar effects related to the particularly high local
Ca2+ concentrations that are achieved (Petrozzino et
al., 1995). In contrast, the more uniform distribution of VSCCs
throughout the plasma membrane may lead to a dilution of
Ca2+ entering through these channels, possibly
resulting in less toxicity.
Oxygen radical production is of mitochondrial origin
Consistent with previous studies (Dugan et al., 1995; Bindokas et
al., 1996), we find that the inhibition of electron transport markedly
attenuated NMDA or kainate-triggered oxygen radical production, suggesting that it is of mitochondrial origin. Indeed, present results
suggest that mitochondria may play a similar role in injury caused by
the activation of Ca2+-permeable AMPA/kainate
channels, as in that caused by NMDA receptor activation where they
clearly have been demonstrated to buffer large Ca2+
loads, with consequent oxygen radical production (Werth and Thayer, 1994; White and Reynolds, 1995, 1997; Wang and Thayer, 1996).
Recent studies have begun to clarify the deleterious effects that may
result from mitochondrial Ca2+ overload. Rapid
Ca2+ uptake causes direct mitochondrial
depolarization (Schinder et al., 1996; White and Reynolds, 1996),
impairment of energy metabolism (Wang et al., 1994), and uncoupling of
electron transport from ATP production (Beatrice et al., 1980; Gunter
and Pfeiffer, 1990), with the resultant release of oxygen radicals
(perhaps particularly superoxide) from the electron transport chain
(Turrens et al., 1985; Coyle and Puttfarcken, 1993). Superoxide, to
which HEt appears to be particularly sensitive (Bindokas et al., 1996),
may be a critical intermediate in acute excitotoxic injury (Lafon-Cazal et al., 1993; Patel et al., 1996) via its conversion into more reactive
oxygen species such as OH or
ONOO (Coyle and Puttfarcken, 1993; Packer et al.,
1996). Thus, mitochondria may be a key cellular organelle responsible
for converting rapid Ca2+ entry caused by the
activation of NMDA channels or Ca2+-permeable
AMPA/kainate channels into neuronal injury. Localization of
mitochondria at dendritic sites of Ca2+ entry
through NMDA and Ca2+-permeable AMPA/kainate
channels may be linked to rapid localized oxygen radical production and
the resultant initiation of injury in dendrites (Bindokas and Miller,
1995).
Disease relevance
Both glutamate-mediated excitotoxicity and oxidative stress have
been implicated in acute neuronal injury such as occurs in ischemia or
trauma, and present results are consistent with a role of AMPA/kainate
receptor-mediated entry in those conditions (Sheardown et al., 1990;
Wrathall et al., 1994). Present findings also may be relevant to the
selective neurodegeneration seen in Alzheimer's disease and
amyotrophic lateral sclerosis, diseases in which many of the neurons
that preferentially degenerate are highly vulnerable to AMPA/kainate
receptor-mediated injury (Hugon et al., 1989; Beal et al., 1991; Page
et al., 1991; Rothstein et al., 1993), likely reflecting the expression
of large numbers of Ca2+-permeable AMPA/kainate
channels (Weiss et al., 1990b; Pruss et al., 1991; Yin et al., 1994b;
Burke et al., 1995; Carriedo et al., 1996). Low-level activation of
Ca2+-permeable AMPA/kainate channels and consequent
oxygen radical production could cause slowly cumulative oxidative
damage to mitochondrial DNA (Mecocci et al., 1993) or cell membranes
(Coyle and Puttfarcken, 1993), eventually contributing to the enhanced
tissue oxidation and impairment of energy metabolism noted in these
diseases (Beal, 1995; Bergeron, 1995; Good et al., 1996; Markesbery,
1997). Indeed, neurons expressing Ca2+-permeable
AMPA/kainate channels might be particularly prone to cumulative
excitotoxic injury because these channels (unlike NMDA channels, which
are blocked by Mg2+ ions at resting potentials)
permit unimpeded high ion flux whenever activated, regardless of
membrane potential.
| |
FOOTNOTES |
Received April 16, 1998; revised June 18, 1998; accepted July 8, 1998.
This work was supported by National Institutes of Health Grant NS 30884 (J.H.W.), grants from the Amyotrophic Lateral Sclerosis Association and
the Pew Scholars Program in the Biomedical Sciences (J.H.W.), and
National Research Service Award Predoctoral Fellowship HG00179
(S.G.C.). We thank Kimberly Claytor for her assistance in cell
culture.
Correspondence should be addressed to Dr. John H. Weiss at the above
address.
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Top
Abstract
Introduction
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