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The Journal of Neuroscience, August 1, 2000, 20(15):5715-5723
Delayed Mitochondrial Dysfunction in Excitotoxic Neuron Death:
Cytochrome c Release and a Secondary Increase in
Superoxide Production
C. Marc
Luetjens1,
Nguyen Truc
Bui1,
Bernd
Sengpiel3,
Gudrun
Münstermann1,
Monika
Poppe1,
Aaron J.
Krohn1,
Elke
Bauerbach3,
Josef
Krieglstein3, and
Jochen H. M.
Prehn1, 2, 3
1 Interdisciplinary Center for Clinical Research,
Research Group "Apoptosis and Cell Death" and
2 Department of Pharmacology and Toxicology, Westphalian
Wilhelms-University, D-48149 Münster, and
3 Department of Pharmacology and Toxicology,
Philipps-University, D-35032 Marburg, Germany
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ABSTRACT |
An increased production of superoxide has been shown to mediate
glutamate-induced neuron death. We monitored intracellular superoxide
production of hippocampal neurons during and after exposure to the
glutamate receptor agonist NMDA (300 µM). During a
30 min NMDA exposure, intracellular superoxide production increased significantly and remained elevated for several hours after wash-out of
NMDA. After a 5 min exposure, superoxide production remained elevated
for 10 min, but then rapidly returned to baseline. Mitochondrial membrane potential also recovered after wash-out of NMDA. However, recovery of mitochondria was transient and followed by delayed mitochondrial depolarization, loss of cytochrome c, and
a secondary rise in superoxide production 4-8 hr after NMDA exposure.
Treatment with a superoxide dismutase mimetic before the secondary rise conferred the same protection against cell death as a treatment before
the first. The secondary rise could be inhibited by the complex I
inhibitor rotenone (in combination with oligomycin) and mimicked by the
complex III inhibitor antimycin A. To investigate the
relationship between cytochrome c release and superoxide
production, human D283 medulloblastoma cells deficient in mitochondrial
respiration (  cells) were exposed to the
apoptosis-inducing agent staurosporine. Treatment with staurosporine
induced mitochondrial release of cytochrome c, caspase
activation, and cell death in control and cells.
However, a delayed increase in superoxide production was only observed
in control cells. Our data suggest that the delayed superoxide
production in excitotoxicity and apoptosis occurs secondary to a defect
in mitochondrial electron transport and that mitochondrial cytochrome
c release occurs upstream of this defect.
Key words:
excitotoxicity; glutamate; NMDA; mitochondria; reactive
oxygen species; superoxide; cytochrome c; respiratory chain; apoptosis
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INTRODUCTION |
Overactivation of glutamate
receptors is responsible for excitotoxic neuron death after trauma,
epileptic seizures, and cerebral ischemia (Choi, 1994 ). In most
experimental and clinical settings, glutamate toxicity is mediated
through activation of Ca2+ permeable NMDA
receptors (Choi, 1994). Reduction of Ca2+
influx or intracellular Ca2+ chelation has
been shown to prevent this process, suggesting that NMDA
receptor-mediated cell death is triggered by neuronal Ca2+ overloading (Choi, 1987; Tymianski et
al., 1993). However, the importance of the diverse events downstream of
neuronal Ca2+ overloading is still
controversial. Ca2+-induced nitric oxide
production and activation of calpains have been shown to contribute to
excitotoxic neurodegeneration (Siman et al., 1989; Dawson et al.,
1991). Mitochondria have been shown to take up large amounts of
Ca2+ during exposure to excitotoxins
(White and Reynolds, 1995; Budd and Nicholls, 1996a,b; Peng and
Greenamyre, 1998). This was initially believed to be a
Ca2+-buffering mechanism that protects
against "toxic" increases in cytosolic
Ca2+ concentration. However, there is now
considerable data suggesting that mitochondrial
Ca2+ uptake is in fact necessary to
trigger excitotoxic neuron death (Budd and Nicholls, 1996a,b; Castilho
et al., 1998; Stout et al., 1998).
Mitochondrial Ca2+ overloading may
activate neuronal cell death by at least three known mechanisms: (1)
energy depletion, (2) release of pro-apoptotic factors, and (3)
increased generation of reactive oxygen species (ROS). Energy depletion
occurs when glutamate receptors are overactivated for a longer period
of time and leads to a severe disturbance of neuronal ion homeostasis and, eventually, necrotic cell death (Ankarcrona et al., 1995). However, transient glutamate receptor overactivation, which is more
likely to occur in acute neurological disorders, may lead to a recovery
of the mitochondrial energetics and a delayed, apoptotic cell death
(Ankarcrona et al., 1995). Mitochondrial
Ca2+ overloading may trigger neuronal
apoptosis via the release of pro-apoptotic factors from the
mitochondrial intermembrane space into the cytosol (Liu et al., 1996;
Andreyev et al., 1998). Release of cytochrome c, in
particular, is able to activate a family of cysteine proteases, the
caspases, which are required for most of the biochemical and
morphological changes leading to apoptosis (Li et al., 1997). Finally
Ca2+-induced mitochondrial dysfunction can
lead to an increased production of ROS, in particular superoxide (Malis
and Bonventre, 1985; Dykens, 1994). Indeed, it has been shown that
mitochondria generate superoxide and related ROS during glutamate
receptor overactivation (Lafon-Cazal et al., 1993; Dugan et al.,
1995; Reynolds and Hastings, 1995; Bindokas et al., 1996; Patel et al.,
1996) and that inhibition of superoxide formation reduces
excitotoxic neuron death (Chan et al., 1990; Patel et al., 1996). In
light of the increasing evidence that mitochondria are able to initiate
excitotoxic and apoptotic neuron death, we investigated the role of
mitochondrial superoxide production and cytochrome c release
in NMDA neurotoxicity and apoptosis.
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MATERIALS AND METHODS |
Materials. Antimycin A, NMDA, oligomycin, paraquat,
rotenone, and staurosporine were from Sigma (Deisenhofen, Germany).
Hydroethidine (HEt) and rhodamine-123 (R-123) were from Molecular
Probes (Leiden, The Netherlands). The cell-permeable superoxide
dismutase (SOD), mimetic manganese tetrakis (4-benzoyl acid), porphyrin
(MnTBP) (Patel and Day, 1999), and the caspase substrate
acetyl-DEVD-7-amido-4-methylcoumarin (Ac-DEVD-AMC) were purchased from
Alexis (Grünstetten, Germany). Dizocilpine and tetrodotoxin were
from RBI Biotrend (Cologne, Germany). All other chemicals came in
analytical grade purity from Merck (Darmstadt, Germany).
Hippocampal neuron culture. Cultured hippocampal neurons
were prepared from neonatal [postnatal day 1 (P1)] Fischer 344 rats as described (Krohn et al., 1998). Dissociated hippocampal neurons were
plated at a density of 2 × 105
cells/cm2 onto
poly-L-lysine-coated glass coverslips that were placed into 35 mm Petri dishes. For cytotoxicity assays, cells were plated onto
poly-D-lysine-coated 24-well plates (Nunc, Wiesbaden,
Germany). Cells were maintained in MEM medium supplemented with 10%
NU-serum, 2% B-27 supplement (50 × concentrate), 2 mM L-glutamine, 20 mM D-glucose, 26.2 mM sodium bicarbonate, 100 U/ml
penicillin, and 100 µg/ml streptomycin (Life Technologies, Karlsruhe,
Germany). All experiments were performed on 14- or 15-d-old cultures.
Animal care followed official governmental guidelines.
Generation and maintenance of human medulloblastoma D283 cells
deficient in mitochondrial respiration. D283 cells originate from
a human cerebellar medulloblastoma and are positive for neurofibrillary proteins, glutamine synthetase, MAP2, and neuron-specific enolase, but
negative for glial fibrillary acidic protein and S-100 protein (Vinores
et al., 1994). Human medulloblastoma D283 cells deficient in
mitochondrial respiration ( cells)
were generated by selective elimination of mitochondrial DNA (mtDNA)
(M. Poppe, G. Münstermann, and J. H. M. Prehn,
unpublished observations). Cells were exposed for 8 weeks to ethidium
(Et) bromide (0.5 µg/ml; Sigma) in RMPI 1460 medium supplemented with glucose (4.5 mg/ml), sodium pyruvate (0.1 mg/ml), and uridine (50 µg/ml) (King and Attardi, 1989), as well as penicillin (100 U/ml),
streptomycin (100 µg/ml), and 10% fetal calf serum (Life Technologies). Reduction of mtDNA content by a controlled Et bromide treatment leads to selective, voltage-driven uptake of Et into mitochondria, intercalation into mtDNA, and inhibition of mtDNA replication. mtDNA encodes subunits of mitochondrial complexes I, III,
and IV that are required for mitochondrial respiration. Because the
oxidative phosphorylation system in these cells is severely inhibited,
cell growth depends on the presence of glucose and pyruvate as key
components. D283 cells maintained
growth but exhibited a significant reduction in mtDNA-encoded proteins
(see Fig. 8a). Withdrawal of pyruvate from the culture
medium led to a rapid cell death of
cells, in contrast to control cells. Moreover, assessment of cytochrome
c oxidase (complex IV) activity according to Vaillant and
Nagley (1995) indicated that mitochondrial respiratory activity of
cells was significantly reduced,
whereas complex II activity was unaltered compared with controls
(Poppe, Münstermann, and Prehn, unpublished observations).
Mitochondrial complex II (succinate dehydrogenase) contains only
nucleus-encoded subunits. Exposure to rotenone, an inhibitor of complex
I, induced significant cell death in control cultures, whereas
cells were resistant even to high
concentrations of this inhibitor (see Fig. 8b). Similar
results were obtained after exposure to the complex III inhibitor
antimycin A (0.01-1 µM).
Induction of excitotoxic neuronal injury. Cultures were
washed in HEPES-buffered saline (HBS) containing (in mM:
144 NaCl, 10 HEPES, 2 CaCl2, 1 MgCl2, 5 KCl, 10 D-glucose (320 mOsm,
pH 7.4) and were then exposed for 5 min (brief exposure) or 30 min (prolonged exposure) to Mg2+-free HBS
supplemented with 300 µM NMDA, 0.5 µM
tetrodotoxin, and 100 nM glycine (Sengpiel et al., 1998).
Control cultures were exposed to Mg2+-free
HBS devoid of NMDA (sham exposure). After the exposure, cells were
washed and returned to the original culture medium. Cell death was
determined with trypan-blue uptake (0.5% in HBS, 5 min), which
identifies membrane leakage, the endpoint of neuronal degeneration. A
total number of 400-500 neurons were counted in three to four
subfields of each culture. Cell counts were performed by two
investigators without knowledge of the respective treatments, and the
mean of the two results was used for statistical analysis.
Induction of apoptotic injury and assessment of caspase
activity. Control and D283
cells were exposed to the apoptosis-inducing protein kinase inhibitor
staurosporine (3 µM) as described (Falcieri et al., 1993;
Krohn et al., 1998). For caspase activity experiments, cells were lysed
in 200 µl of lysis buffer [10 mM HEPES, pH 7.4, 42 mM KCl, 5 mM MgCl2, 1 mM phenylmethylsulfonyl fluoride, 0.1 mM EDTA,
0.1 mM EGTA, 1 mM dithiothreitol, 1 µg/ml
pepstatin A, 1 µg/ml leupeptin, 5 µg/ml aprotinin, 0.5%
3-(3-cholamidopropyldimethyl-ammonio)-1-propane sulfonate]. Fifty
microliters of this extract were added to 150 µl of reaction buffer
[25 mM HEPES, 1 mM EDTA, 0.1%
3-(3-cholamidopropyldimethylammonio)-1-propane sulfonate, 10% sucrose,
3 mM dithiothreitol, pH 7.5] (Krohn et al., 1998). The
reaction buffer was supplemented with 10 µM Ac-DEVD-AMC, a fluorogenic substrate preferentially cleaved by caspase-3, -7, and
-8, but also caspase-1, -6, -9, and -10. Production of fluorescent AMC
was monitored over 60 min using a fluorescent plate reader (HTS 7000, Perkin-Elmer, Langen, Germany) (excitation 380 nm, emission 460 nm).
Fluorescence of blanks containing no cellular extracts was substracted
from the values. Protein content was determined using the Pierce
Coomassie Plus Protein Assay reagent (KMF, Cologne, Germany), and the
caspase activity is expressed as change in fluorescent units per hour
per microgram of protein.
HEt-based detection of intracellular superoxide production.
Superoxide production of the hippocampal neurons was monitored by
digital video microscopy using the probe HEt (Bindokas et al., 1996).
HEt is taken up by living cells and oxidized by superoxide to its
fluorescent product, Et. Et is retained intracellularly by stably
binding to DNA and RNA. Digital video microscopy was conducted as
described (Sengpiel et al., 1998) using a fluorescence microscope
(Axiovert 100 inverted-stage microscope, Zeiss). Optics were as
follows: excitation of 490 nm, dichroic mirror of 505 nm, and
emission > 510 nm. Images were collected using a 40×
fluorescence objective and an intensified CCD camera (C 2400-87,
Hamamatsu, Herrsching, Germany). Sixteen frames were averaged every 20 sec. Images were digitized as 256 × 256 pixels. Before every
experiment, a background image was taken that was later substracted
from the images. Data were analyzed using Argus-50 software
(Hamamatsu). HEt (2 µg/ml) was present in the extracellular solution
during the entire experiment. The extracellular solution was exchanged every 5 min by a fresh solution. In the experiment shown in Figure 7,
Et fluorescence was acquired using a 12-bit digital CCD camera (Visicam
Visitron) and analyzed using Metamorph software (Universal Imaging
Corporation, West Chester, PA). Experiments were conducted at room temperature.
Under conditions of mitochondrial depolarization and prolonged HEt
exposure, mitochondrially generated Et may be released into the
cytoplasm, resulting in an artificial fluorescence enhancement (Castilho et al., 1999). We therefore additionally quantified Et
fluorescence of hippocampal neuron cultures after homogenizing the
cells in lysis buffer (10% SDS, 0.1 M Tris, pH 7.5). Et
fluorescence of cell lysates was quantified using a fluorescence plate
reader (FL 500, Biotek; excitation 485 nm, emission 530 nm). Lysis
buffer served as blanks. Protein content was determined using the
Pierce BCA Micro Protein Assay kit (KMF), and Et fluorescence of cell lysates was expressed as fluorescence units per microgram of protein.
R-123-based estimation of mitochondrial membrane potential
(  m). R-123 is a cationic, lipophilic dye that accumulates in the negatively charged mitochondrial matrix according to the Nernst equation potential (Emaus et al., 1986; Ehrenberg et al., 1988). An
R-123 stock was prepared at a concentration of 1 mg/ml in DMSO and
stored at  20°C. Working stocks of 30 µM were made up
fresh in distilled water. For estimation of
m during the NMDA exposure, cells were
incubated with 30 nM R-123 for 15 min in culture medium and
were then exposed for 5 min to NMDA (300 µM) or
Mg2+-free HBS (sham). For the estimation
of m 2 and 6 hr after the NMDA exposure,
cells were exposed to NMDA or Mg2+-free
HBS (sham) for 5 min and returned to the original culture medium. After
2 or 6 hr, cells were loaded with 30 nM R-123 for 15 min in
culture medium, and fluorescence was acquired. R-123 fluorescence was
measured using an inverted Olympus IX70 microscope attached to a
confocal laser scanning unit equipped with a 488 nm argon laser and a
20× fluorescence objective (Fluoview; Olympus, Hamburg, Germany). The
dye was present in the extracellular solution during the entire course
of the data collection. The regions of interest were monitored and
focused by eye and then scanned once. Neurons were recognized by
morphology as well as by their position in a higher plane than
astrocytes. We obtained two images per scan: a transmission and a
confocal fluorescence image. Data were analyzed using Metmorph
software. Fluorescence data are given as the ratio between the average
pixel intensity of the neuronal soma and the nucleus according to Wadia
et al. (1998) to compensate for background differences and unequal
R-123 loading.
Cytochemical detection of intracellular superoxide
production. Intracellular superoxide production was cytochemically
detected using the 3,3'-diaminobenzidine (DAB)/Mn method in which DAB
is oxidized by Mn3+ derived from
Mn2+ on oxidation by superoxide (Briggs et
al., 1986). Hippocampal neurons were incubated for 60 min at 37°C in
HBS supplemented with 2.5 mM DAB, 0.5 mM
MnCl2 and 1 mM
NaN3 in the presence or absence of mitochondrial
respiratory chain inhibitors and in the presence of 1 µM
dizocilpine. The cytochemical reaction was terminated by fixing the
cells. Neurons with brown precipitates were considered positive and
quantified by cell counting as described above.
Immunofluorescence microscopy and labeling of mitochondria.
After exposure to NMDA, hippocampal neurons or D283 cells were washed,
fixed and permeabilized. The primary antibody (mouse monoclonal anti-cytochrome c, 6H2.B4; PharMingen, San Diego, CA) was
then added at a concentration of 10 µg/ml for 2 hr at room
temperature in blocking buffer. After washing, Cy3-conjugated
anti-mouse IgG (1:1000, Jackson Immunoresearch Laboratories, West
Grove, PA) was added for 1 hr. Mitochondria were labeled using the
potential-insensitive probe Mitotracker Green FM (200 nM) (Molecular Probes) before fixation as
described previously (Krohn et al., 1999). In another set of
experiments, mitochondria were labeled using a rabbit polyclonal anti-SOD-2 antibody (StressGene, Victoria, Canada) raised against rat
SOD-2 diluted 1:300. Fluorescence was observed using an Eclipse TE300
inverted microscope (Nikon, Düsseldorf, Germany). Digital images
of equal exposure were acquired using a SPOT-2 digital camera
(Diagnostic Instruments, Sterling Heights, MI) and Metamorph software.
Cytochrome c immunofluorescence of D283 cells was observed by confocal laser scanning microscopy as described above.
SDS-PAGE and Western blotting. D283 cells were rinsed with
ice-cold PBS and lysed in Tris-buffered saline containing SDS, glycerin, and protease inhibitors. Protein content was determined using
the Pierce BCA Micro Protein Assay kit, and samples were supplemented
with 2-mercaptoethanol and denaturated at 95°C for 5 min. An equal
amount of protein (20 µg) was separated with SDS-PAGE and blotted to
nitrocellulose membranes (Protean BA 85; Schleicher & Schuell, Dassel,
Germany). Nonspecific binding was blocked by incubation in
Tris-buffered saline containing bovine serum albumin, non-fat dry milk,
and 0.05% Tween-20 for 1 hr at room temperature. The blots were then
incubated overnight at 4°C in blocking buffer containing the primary
antibody. Antibodies used were a mouse monoclonal anti-cytochrome
oxidase subunit I antibody (1D6-E1-A8; Molecular Probes) diluted 1:500,
a rabbit polyclonal anti-Bcl-x antibody (kindly provided by Prof. C. Thompson, University of Pennsylvania) diluted 1:2000, or a mouse
monoclonal anti- -tubulin antibody (clone DM 1A; Sigma) diluted
1:1,000. Afterward, membranes were washed and incubated with anti-mouse
or anti-rabbit IgG-horseradish peroxidase conjugate (1:5000; Promega,
Mannheim, Germany). Antibody-conjugated peroxidase activity was
visualized using the SuperSignal chemiluminescence reagent (Pierce,
Rockford, IL).
Statistics. Data are given as means ± SEM. For
statistical comparison, t test or one-way ANOVA followed by
Tukey's test were used. For statistical comparison of Et and R-123
fluorescence data, Mann-Whitney U test and Kruskal-Wallis
H-test for non-parametric data were used. P values smaller
than 0.05 were considered to be statistically significant.
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RESULTS |
Excitotoxic neuron death is sensitive to treatment with a
cell-permeable SOD mimetic
To induce a Ca2+-dependent
excitotoxic cell death, we exposed cultured rat hippocampal neurons to
the selective glutamate receptor agonist NMDA (300 µM). A
5 min exposure to NMDA induced excitotoxic cell death in 36.3 ± 2.0% of the hippocampal neurons determined by the uptake of the
membrane-impermeable dye trypan blue 24 hr after the exposure (Fig.
1). Prolonging the period of the NMDA exposure to 30 min increased excitotoxic neurodegeneration to 62.6 ± 4.9%. In agreement with previous reports demonstrating an important
role of ROS in excitotoxic neuron death, NMDA-induced cell death after
a brief or prolonged exposure was significantly reduced in cultures
pretreated for 60 min with the cell-permeable SOD mimetic MnTBP (100 µM) (Fig. 1) or the lipophilic antioxidant (±)--tocopherol (100 µM) (data not shown). Despite
the common sensitivity to antioxidant treatment, there were differences
in the mode of cell death after the 5 and 30 min NMDA exposure.
Immediately after termination of the 30 min NMDA exposure, there was a
statistically significant increase in the percentage of trypan
blue-positive cells that further increased over time. In contrast,
after the 5 min NMDA exposure the percentage of damaged neurons did not increase up to 2 hr, but tended to increase after 4 hr, and eventually reached the level of statistical significance after 8 hr (Table 1).
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Figure 1.
Neuroprotection by the SOD mimetic MnTBP. Cultured
rat hippocampal neurons were exposed to 300 µM NMDA in
Mg2+-free HBS for either 5 or 30 min, washed, and
returned to the original culture medium. Sham-washed cultures were
exposed for 30 min to Mg2+-free HBS devoid of NMDA.
Cultures were pretreated for 60 min with 100 µM MnTBP
(MnT) or vehicle (Veh). Treatments
were continued during and after the NMDA exposure. Cell death was
quantified by trypan-blue uptake after 24 hr. Data are means ± SEM from n = 8-16 cultures in two to four
experiments per treatment. Different from 5 min NMDA-exposed controls:
*p < 0.05; different from 30 min NMDA-exposed
controls: # p < 0.05.
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Table 1.
Time course of neuronal degeneration after brief (5 min) or
prolonged (30 min) exposure of cultured rat hippocampal neurons to
NMDA
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Recovery of mitochondrial superoxide production after toxic
glutamate receptor overactivation
Because ROS appeared to be required for the expression of
excitotoxic neuron death, we next monitored the time course of
superoxide production during and after NMDA exposure. Superoxide
production was determined with the oxidation-sensitive probe HEt in
combination with digital video microscopy (Bindokas et al., 1996).
Control experiments demonstrated a constant rate of HEt oxidation in
cultures exposed to buffer (HBS) only (data not shown). When cells were continuously exposed to NMDA (300 µM), HEt oxidation
increased significantly with a maximal rate after 10 min of exposure
(Fig. 2a). We and others have
shown previously that NMDA-induced Ca2+
influx and the subsequent production of superoxide via the
mitochondrial respiratory chain cause this increase, because both
removal of extracellular Ca2+ or
pretreatment with inhibitors of mitochondrial complex I reduced NMDA-induced superoxide production (Dugan et al., 1995; Sengpiel et
al., 1998; Castilho et al., 1999). Interestingly, when cells were
exposed to NMDA for only 5 min (which was sufficient to cause excitotoxic neuron death), superoxide production remained elevated for
a further 10 min period after wash-out of NMDA but then rapidly returned to baseline levels (Fig. 2b).
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Figure 2.
Superoxide production during and after exposure to
NMDA. Cultures were incubated with HBS supplemented with 2 µg/ml HEt.
The rate of HEt oxidation was determined in 5 min intervals using
digital video microscopy. Extracellular solution was exchanged every 5 min by a fresh solution. a, Superoxide production
increases during exposure to NMDA. Cultures were exposed for 5 min to
Mg2+-free HBS (H) to
record baseline superoxide production and were then exposed to NMDA
(300 µM). b, Recovery of intracellular
superoxide production after a brief glutamate receptor overactivation.
Cultured rat hippocampal neurons were exposed to
Mg2+-free HBS (H) for 5 min to record baseline superoxide production, and were then exposed to
300 µM NMDA for 5 min (N).
Afterward, extracellular solution was exchanged for HBS supplemented
with 1 µM of the NMDA antagonist dizocilpine. Data are
means ± SEM from n = 27 and 65 neurons in
four and nine experiments per treatment, respectively. Different from
baseline superoxide production (HBS): *p < 0.05. A.U., Arbitrary fluorescence unit.
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Delayed mitochondrial depolarization after toxic glutamate
receptor overactivation
Mitochondrial depolarization has been shown to be an early signal
specific for excitotoxin exposure (White and Reynolds, 1996). Moreover,
it has been reported that delayed excitotoxic neuron death is
associated with a recovery of mitochondrial membrane potential after
excitotoxin exposure (Ankarcrona et al., 1995). We were therefore
interested to determine the uptake of R-123, a voltage-sensitive probe
that is widely used to detect changes in mitochondrial membrane
potential, during and after the 5 min NMDA exposure. In cultures
exposed to NMDA for 5 min, we observed a tendency toward a decrease in
neuronal R-123 fluorescence ratios, which, however, did not reach the
level of statistical significance (Student's t test:
p = 0.231; Mann-Whitney U test:
p = 0.712; n = 110 NMDA-exposed and
n = 129 sham-exposed neurons in three separate
experiments per treatment), suggesting that mitochondrial depolarization was absent or below the level of detection (Fig. 3). Moreover R-123 fluorescence ratios 2 hr after exposure to NMDA were indistinguishable from that of
sham-exposed controls. However, a significant decline in the R-123
fluorescence ratio was observed 6 hr after the NMDA exposure,
suggesting a delayed mitochondrial depolarization.
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Figure 3.
Mitochondrial potential changes during and after
brief NMDA exposure. Live confocal microscopy imaging of R-123 uptake
was performed in hippocampal neurons after a 5 min exposure to NMDA
(300 µM) or Mg2+-free HBS
(Sham), as well as 2 or 6 hr after the respective
exposure. a, Histograms showing the average R-123
fluorescence ratio between the soma and the nucleus. Note that 6 hr
after exposure to NMDA, neurons had a significantly lower ratio then in
all other experimental configurations. Data are means ± SEM from
n = 25-136 neurons and n = 3 separate experiments per treatment. Difference between respective NMDA-
and sham-exposed cells: *p < 0.05. n.s., Not statistically significant. b,
Top row, Confocal R-123 fluorescence images;
bottom row, bright-field (BF)
images. Images demonstrate different hippocampal neurons after sham
exposure, 2 hr after, or 6 hr after a 5 min NMDA exposure. The sham and
the 2 hr NMDA experiment show neurons with a clear fluorescence signal
in the soma and almost none in the nucleus region; however, the 6 hr
NMDA experiment shows a decrease in the cytoplasmic R-123 fluorescence,
as well as an increased fluorescence in the nuclei, leading to an
almost equally distributed R-123 dye. Scale bar, 10 µm.
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Glutamate receptor overactivation induces mitochondrial cytochrome
c release
Delayed excitotoxicity associated with a recovery of mitochondrial
energetics has been suggested to exhibit features of apopototic cell
death (Ankarcrona et al., 1995). Mitochondrial cytochrome c
release is an important upstream trigger to activate apoptosis (Liu et
al., 1996; Li et al., 1997) and in some systems is accompanied by
mitochondrial depolarization (Kroemer et al., 1998; but see Bossy-Wetzel et al., 1998; Krohn et al., 1998, 1999). Therefore, we
investigated changes in cytochrome c distribution after a 5 min NMDA exposure by immunofluorescence microscopy using a monoclonal antibody specific for native cytochrome c. In sham-exposed controls, cytochrome c immunoreactivity was distributed in the
cytoplasm in a rod-like pattern that excluded the nucleus (Fig.
4). In cells exposed for 5 min to NMDA, a
delayed loss of mitochondrial cytochrome c
immunofluorescence occurred. Cytochrome c immunoreactivity
was largely intact 2 hr after the NMDA exposure and colocalized with the potential-insensitive mitochondrial marker, Mitotracker Green FM.
By 8 hr, in contrast, the majority of the hippocampal neurons showed
decreased, diffuse cytochrome c immunofluorescence. In these
cells, mitochondria could still be labeled with Mitotracker Green FM or
by double-staining with an antibody against the mitochondrial matrix
protein SOD-2. Quantification of cells that remained positive for
mitochondrial markers and excluded trypan-blue revealed that cytochrome
c loss occurred in 54.2 ± 2.7% of the hippocampal
neurons, compared with 4.9 ± 0.4% in sham-exposed controls and
7.9 ± 0.2% in cultures 2 hr after the NMDA exposure (data from
three separate experiments per treatment).
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Figure 4.
Loss of mitochondrial cytochrome c
after glutamate receptor overactivation.
a-c, Control culture 8 hr after sham
exposure showing a punctate or rod-like cytochrome c
immunofluorescence pattern that overlaps with Mitotracker Green FM
fluorescence. d-f, Hippocampal neurons 2 hr after NMDA exposure (300 µM, 5 min). Note that
cytochrome c immunofluorescence was largely intact and
colocalized with Mitotracker Green. g-i,
Eight hours after the NMDA exposure, hippocampal neurons lost their
cytochrome c immunofluorescence, whereas Mitotracker
Green FM fluorescence was largely preserved.
j-l, Control culture 8 hr after sham
exposure showing overlap of cytochrome c and SOD-2
immunofluorescence. m-o, Culture exposed
to 300 µM NMDA for 5 min and fixed after 8 hr. Note a
decreased and diffuse cytochrome c staining pattern,
whereas SOD-2 immunofluorescence remained intense and punctate. Scale
bar, 25 µm.
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Loss of cytochrome c is accompanied by a secondary
increase in mitochondrial superoxide production
A pronounced loss of cytochrome c as seen after NMDA
exposure could be associated with a disruption of the mitochondrial
electron transport and accumulation of reducing equivalents in the
respiratory chain. One potential consequence thereof is an increased
formation of superoxide attributable to a shift from the normal
four-electron reduction of molecular oxygen to an one-electron
reduction (Boveris et al., 1976; Turrens and Boveris, 1980). We were
therefore interested in quantifying superoxide production in the
hippocampal neuron cultures after the mitochondrial release of
cytochrome c. Under conditions of mitochondrial
depolarization (Fig. 3), mitochondrially generated Et may be released
into the cytoplasm, resulting in an artificial fluorescence enhancement
(Castilho et al., 1999). We therefore quantified the amount of HEt
oxidized to Et over a period of 30 min in cell lysates prepared at
various time points after a 5 min NMDA exposure. In support of the
above hypothesis, we observed a secondary burst in superoxide
production that reached the level of statistical significance after 4 hr (Fig. 5a). The lysate
method also detected the immediate increase in HEt oxidation occurring
during and shortly after a 5 min NMDA exposure [25.4 ± 1.8 arbitrary fluorescence unit (AU)/µg protein in cultures exposed for 5 min to NMDA and allowed to recover for 25 min vs 14.0 ± 2.8 AU/µg protein in sham-exposed cultures; n = 4 cultures per treatment; p = 0.015]. After the 30 min
NMDA exposure, superoxide production remained elevated at a constant
level for up to 8 hr (Fig. 5b).
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Figure 5.
Delayed superoxide production in excitotoxic
neuron death. Cultured rat hippocampal neurons were exposed to 300 µM NMDA for either 5 min (a) or 30 min (b). Sham-washed cultures were exposed to
Mg2+-free HBS. At the indicated time points after
the exposure, cultures were treated with HEt (10 µg/ml) for 30 min at
37°C. Afterward, cells were homogenized with lysis buffer, and Et
fluorescence of cellular extracts was quantified using a fluorescence
microplate reader. Et fluorescence data are normalized for protein
content. Data are means ± SEM from n = 6-8
cultures. Different from sham-exposed controls: *p < 0.05. The experiment was performed in triplicate
(a) or duplicate (b) and
yielded comparable results.
|
|
To verify our finding of the delayed increase in superoxide production
with a different assay, we used a DAB/Mn cytochemical method to detect
intracellular superoxide formation (Fig.
6). Cultures were exposed to
Mg2+-free HBS (sham) or NMDA for 5 min and
analyzed after 6 hr. A 5 min exposure to NMDA increased the percentage
of positively stained neurons significantly. A treatment with the
complex I inhibitor rotenone (2 µM) in combination with
oligomycin (2 µM) to inhibit reversal of the
mitochondrial ATP synthase (Budd and Nicholls, 1996a,b; Sengpiel et
al., 1998) significantly decreased the delayed superoxide production,
suggesting that the origin of the superoxide was mainly mitochondrial
(Fig. 6).
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Figure 6.
Cytochemical detection of superoxide production in
cultured rat hippocampal neurons after glutamate receptor
overactivation. Cultured rat hippocampal neurons were exposed for 5 min
to NMDA (300 µM) or Mg2+-free HBS
(Sham), washed, and returned to the original culture
medium. After 6 hr, the culture medium was replaced by HBS supplemented
with 2.5 mM DAB, 0.5 mM
MnCl2, 1 mM NaN3, 1 µM of the NMDA antagonist dizocilpine and mitochondrial
respiratory chain inhibitors rotenone (2 µM) plus
oligomycin (2 µM) (R/O), antimycin A (10 µM) (AA), or vehicle (Veh).
As a negative control, the reaction was performed in the absence of
MnCl2 (Mn). Cultures were incubated for 60 min at 37°C, fixed, and analyzed for positive staining.
a-d, Bright-field images of hippocampal
neuron cultures 6 hr after sham exposure or NMDA exposure and treatment
with or without antimycin A. Arrows indicate neurons
with cytoplasmic precipitates. Scale bar, 50 µm. e,
Quantification of Mn/DAB staining. Data are means ± SEM from six
cultures in two separate experiments. *p < 0.05:
difference between sham- and NMDA-exposed cultures;
# p < 0.05: different from
sham-exposed cultures.  p < 0.05:
different from NMDA-exposed cultures (ANOVA and Tukey's test;
p < 0.05).
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Disruption of electron flow at the level of complex III increases
superoxide production
We then addressed the question of whether loss of cytochrome
c could be functionally related to the secondary increase in superoxide production. Cytochrome c shuttles electrons
between complexes III and IV of the mitochondrial respiratory chain.
Treatment with the mitochondrial complex III inhibitor antimycin A (10 µM) also increased superoxide production in the
hippocampal neurons shown by the DAB/Mn cytochemical assay (Fig. 6). An
increased superoxide production after an exposure to antimycin A was
also detected by quantifying HEt oxidation in individual hippocampal neurons (Fig. 7a).
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Figure 7.
Antimycin A- and paraquat-induced superoxide
production after exposure to NMDA. Cultured rat hippocampal neurons
were exposed to 300 µM NMDA or
Mg2+-free HBS (Sham) for 5 min,
washed, and returned to the original culture medium. After 8 hr,
cultures were incubated at 37°C in HBS supplemented with 2 µg/ml
HEt plus 1 µM dizocilpine, and 10 µM
antimycin A (a), 100 µM paraquat
(b), or vehicle. Et production of individual
hippocampal neurons was quantified by fluorescence microscopy. Data are
means ± SEM from n = 174-373 neurons in two
separate experiments per treatment. *p < 0.05:
Different from sham-exposed controls;
# p < 0.05: different from
NMDA-exposed controls; p < 0.05:
different from respective drug-treated control.
n.s., Not statistically significant.
A.U., Arbitrary fluorescence units.
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|
If electron flow was already inhibited at the level of complex III by a
treatment with antimycin A, the NMDA-induced loss of cytochrome
c should fail to stimulate a further increase in superoxide
production. In fact, quantification of HEt oxidation demonstrated that
NMDA failed to stimulate a secondary increase in superoxide production
in cultures treated with antimycin A (Fig. 7a). In contrast,
NMDA was able to stimulate a secondary increase in superoxide
production in cultures treated with paraquat (100 µM), a redox cycling agent that increases
superoxide independently of the activity of the mitochondrial
respiratory chain (Smith et al., 1978) (Fig. 7b).
Cytochrome c release upstream of mitochondrial
superoxide production
To establish whether superoxide production occurs upstream or
downstream of mitochondrial cytochrome c release, we
performed experiments in D283 cells lacking a functional respiratory
chain ( cells). As shown in Figure
8a,
cells lacked expression of the
mtDNA-encoded cytochrome oxidase subunit I. In contrast, expression of
nuclear encoded proteins, including the anti-apoptotic protein Bcl-xl
and the cytoskeletal protein -tubulin, remained unchanged. Because
D283 cells have no functional glutamate receptors, cytochrome
c release was induced by an exposure to the
apoptosis-inducing agent staurosporine. D283
cells showed resistance to the toxic
effect of the complex I inhibitor rotenone but were killed by
staurosporine as readily as D283 control cells (Figs.
8b,c). Confocal laser scanning microscopy revealed that both control and cells
released cytochrome c from mitochondria after treatment with
3 µM staurosporine, resulting in a diffuse
cytochrome c immunofluorescence and a redistribution of the
immunofluorescence into the nucleus (Fig. 8d). Because
release of cytochrome c triggers the activation of caspases,
we determined caspase-3-like protease activity in cell lysates of
control and cells after the exposure
to staurosporine. This treatment caused a significant increase in
cleavage of the fluorigenic substrate Ac-DEVD-AMC in both cell
types (Fig. 8e). However, an increased production of
superoxide was observed only in control cells (Fig. 8f).
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Figure 8.
Cytochrome c release, caspase
activation, and superoxide production in medulloblastoma D283 control
and cells. a, Western blot analysis
showing reduced expression of cytochrome oxidase subunit I in
cells, whereas expression of Bcl-xl and -tubulin
remains unchanged. b, Rotenone is toxic to control
cells, whereas cells are resistant. Cells were
incubated with rotenone, and cell viability was determined after 24 hr.
Data are means ± SEM from n = 8 cultures per
treatment. c, D283 control and cells
are equally sensitive to the apoptosis-inducing agent staurosporine.
Cultures were exposed to staurosporine for 24 hr. Data are means ± SEM from n = 8 cultures per treatment.
d, Cytochrome c release in D283 control
and cells detected 6 hr (Con) and 8 hr
() after exposure to 3 µM staurosporine
by immunofluorescence analysis and confocal laser scanning microscopy.
Note the diffuse staining pattern in either cell type. Scale bar, 25 µm. e, Caspase-3-like protease activity increases in
both D283 control and cells. Cytosolic extracts were
prepared 6 hr (Con) and 8 hr () after
the exposure to staurosporine. Cleavage of fluorigenic Ac-DEVD-AMC was
monitored over 1 hr using a fluorescent plate reader. Data are
means ± SEM from n = 8 cultures per
treatment. f, Superoxide production in D283 control and
cells. Cultures were exposed to 3 µM
staurosporine for 6 hr (Con) and 8 hr
() and treated with HEt (10 µg/ml) for the last 30 min of the exposure. Afterward, cells were homogenized with lysis
buffer, and Et fluorescence of cellular extracts was quantified using a
fluorescence microplate reader. Data are means ± SEM from
n = 15 and 16 cultures, respectively. Different
from respective vehicle-treated cultures: *p < 0.05.
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|
Delayed administration of a SOD mimetic rescues neurons from
excitotoxic neuron death
Finally, we investigated the importance of the delayed superoxide
production for excitotoxic neuron death by determining the effect of a
post-treatment with the SOD mimetic MnTBP. Treatment with MnTBP 2 hr
after termination of the 5 min NMDA exposure (after the first increase
in superoxide production, but before the secondary increase) conferred
a similar degree of protection as achieved with the 1 hr pretreatment
(Fig. 9; compare with Fig. 1). In
contrast, MnTBP exerted no effect when administered 2 hr after a 30 min NMDA exposure (Fig. 9).
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Figure 9.
Post-treatment with the SOD mimetic MnTBP rescues
hippocampal neurons from excitotoxic cell death. Cultured rat
hippocampal neurons were exposed for 5 or 30 min to NMDA (300 µM) or Mg2+-free HBS
(Sham), washed, and returned to the original culture
medium. Two hours after the exposure, cultures received 100 µM MnTBP (MnT) or vehicle
(Veh). After 22 hr, cell death was quantified by
trypan-blue exclusion. Data are means ± SEM from
n = 8-12 cultures in two to three separate
experiments per treatment. Different from respective 5 min NMDA-exposed
controls: *p < 0.05. n.s., Not
statistically significant.
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|
Interestingly, post-treatment of the hippocampal neuron cultures with
the mitochondrial Ca2+ uptake inhibitor
ruthenium red (25 µM) 2 hr after termination of the 5 min
NMDA exposure was also able to reduce excitotoxic neuron death
(19.9 ± 3.1% cell death in ruthenium red-treated, NMDA-exposed
cultures vs 35.3 ± 2.4% cell death in NMDA-exposed cultures;
p < 0.05; n = 4 cultures per
treatment), supporting the concept of delayed mitochondrial dysfunction.
| |
DISCUSSION |
In the present study, we demonstrate that a brief exposure of
cultured rat hippocampal neurons to the glutamate receptor agonist NMDA
induced a delayed excitotoxic neuron death associated with a biphasic
increase in superoxide production. The initial increase occurs during
and shortly after the NMDA exposure. Cellular
Ca2+ overloading and subsequent production
of superoxide via the mitochondrial respiratory chain have been shown
to cause this immediate increase (Dugan et al., 1995; Reynolds and
Hastings, 1995; Bindokas et al., 1996; Sengpiel et al., 1998). The
initial superoxide production rapidly returns to baseline levels after
wash-out of NMDA, and mitochondria remain polarized (Figs. 2, 3).
However, recovery of mitochondria is transient and subsequently
followed by a delayed mitochondrial depolarization, release of
cytochrome c, and a secondary rise in superoxide production
(Figs. 3-5).
Mitochondrial Ca2+ overloading could be
the key process to trigger both the immediate, potentially reversible,
and the delayed mitochondrial dysfunction. Inhibition of mitochondrial
Ca2+ uptake by mitochondrial
depolarization during or shortly after glutamate receptor
overactivation is able to prevent mitochondrial Ca2+ overloading and excitotoxic neuron
death (Budd and Nicholls, 1996b; Castilho et al., 1998; Sengpiel et
al., 1998; Stout et al., 1998). Peng and coworkers (1998) have recently
demonstrated a prolonged mitochondrial
Ca2+ overloading persisting after NMDA
receptor overactivation in cultured striatal neurons. It is conceivable
that this prolonged mitochondrial Ca2+
overloading induces a disturbance of mitochondrial functions that
worsens over time, leading to mitochondrial depolarization and
cytochrome c release. Alternatively, it is possible that
mitochondria receive a second challenge once the excitotoxic cascade is
activated. Lipid peroxidation, activation of proteases and lipases, or
mitochondrial-independent generation of ROS may trigger a delayed
dysfunction (Siman et al., 1989; Dawson et al., 1991; Choi, 1994). The
role of delayed mitochondrial Ca2+
accumulation was supported in the present study by the protective effect of the mitochondrial Ca2+ uptake
inhibitor ruthenium red administered 2 hr after the NMDA exposure. This
protective effect appears to be equally or even more potent than those
of NMDA antagonists or voltage-sensitive Ca2+ channel blockers when administered
after excitotoxin exposure (Hartley and Choi, 1989; Prehn et al.,
1995).
NMDA-induced mitochondrial Ca2+ uptake may
result in increased permeability of the outer mitochondrial membrane
and subsequent loss of the pro-apoptotic factor cytochrome c
(Fig. 4). Ca2+-induced cytochrome
c release may involve the opening of the mitochondrial permeability transition pore or pore-independent pathways (Andreyev and
Fiskum, 1999; He et al., 2000). Although many studies have focused on
the role of cytochrome c release to activate the caspase cascade (Liu et al., 1996; Li et al., 1997), loss of cytochrome c may also affect mitochondrial respiration and free radical
production. Cytochrome c transports electrons between
mitochondrial complexes III and IV. A disruption of the mitochondrial
electron flow caused by a significant loss of cytochrome c
will maintain complex I and the ubiquinone at complex II in the reduced
state. This condition has previously been shown to favor one-electron
reduction of molecular oxygen, presumably because of an autooxidation
of complex I and ubiquinone (Boveris et al., 1976; Turrens and Boveris,
1980). This is a potential mechanism for the well known effect of
complex III and IV inhibitors to increase the mitochondrial production of superoxide (Figs. 6, 7). In fact, inhibition of mitochondrial electron transfer at the level of complex I (under conditions that
inhibit reversal of the mitochondrial ATP synthase) significantly reduced the secondary increase in superoxide production after NMDA
exposure (Fig. 6).
Interestingly, cytochrome c release and superoxide
production also occur at similar time points in the death cascade
during trophic factor withdrawal- or staurosporine-induced neuronal
apoptosis (Greenlund et al., 1995; Deshmukh and Johnson, 1998; Krohn et al., 1998, 1999; Martinou et al., 1999). Inhibition of mitochondrial electron flow and increased mitochondrial superoxide production secondary to cytochrome c release have been observed during
Fas- and staurosporine-mediated apoptosis of Jurkat and HL60 cells (Krippner et al., 1996; Cai and Jones, 1998). In support of these data,
NMDA failed to stimulate a secondary increase in superoxide production
when electron flow through complex III was already inhibited by
antimycin A (Fig. 7). Moreover, in a neural cell line deficient in
mitochondrial respiration (medulloblastoma D283 cells), cytochrome c
release and activation of apoptosis were preserved, whereas an
increased superoxide production could not be detected (Fig. 8) (also
see Jiang et al., 1999). Therefore, cytochrome c release
occurs upstream of mitochondria-derived ROS production.
It should also be noted that previous studies have found little
evidence for a prominent activation of executioner caspases after
glutamate receptor overactivation (Armstrong et al., 1997; Yu et al.,
1999; Lankiewicz et al., 2000). The discrepancy between mitochondrial
cytochrome c release and the lack of activation of
executioner caspases in our model of excitotoxic neuron death has been
shown to be attributable to Ca2+- and
calpain-dependent suppression of the caspase cascade (Lankiewicz et
al., 2000). On the other hand, the protective effect of post-treatment with the SOD mimetic MnTBP demonstrated that the secondary production of superoxide played an important role in the execution of excitotoxic neuron death (Fig. 9). Assuming that the delayed production of superoxide is caused by mitochondrial cytochrome c release
(see Discussion above), loss of cytochrome c may induce cell
death independent of caspases. Likewise, in several models of neuronal apoptosis, inhibition of executioner caspases is able to reduce the
biochemical and morphological signs of apoptosis but does not
necessarily inhibit cell death (Stefanis et al., 1996; Taylor et al.,
1997; Krohn et al., 1998). On the other hand, inhibition of superoxide
production has been shown to protect against neuronal apoptosis
(Greenlund et al., 1995; Jordan et al., 1995; Schulz et al., 1996;
Krohn et al., 1998). Therefore, delayed mitochondrial superoxide
production may significantly contribute to neuron death in
excitotoxicity and apoptosis.
| |
FOOTNOTES |
Received Feb. 22, 2000; revised May 4, 2000; accepted May 9, 2000.
This work was supported by Interdisciplinary Center for Clinical
Research (IZKF), Universität Münster (Bundesministerium für Bildung, Wissenschaft, Forschung und Technologie Grant 01 KS
9604/0) and DFG (Pr 338/9-1 and Forschergruppe "Neuroprotektion"). We thank Christiane Schettler for technical assistance.
C.M.L. and N.T.B. contributed equally to this work.
Correspondence should be addressed to Dr. Jochen H. M. Prehn,
Interdisciplinary Center for Clinical Research (IZKF), Research Group
"Apoptosis and Cell Death," Faculty of Medicine, Westphalian Wilhelms-University, Röntgenstrasse 21, D-48149 Münster,
Germany. E-mail: prehn{at}uni-muenster.de.
| |
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ABSTRACT
INTRODUCTION
