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The Journal of Neuroscience, September 1, 2001, 21(17):6608-6616
The Mitochondrial Permeability Transition Pore and Nitric Oxide
Synthase Mediate Early Mitochondrial Depolarization in Astrocytes
during Oxygen-Glucose Deprivation
Susan A.
Reichert,
Jeong Sook
Kim-Han, and
Laura L.
Dugan
Department of Neurology and Center for the Study of Nervous System
Injury, Washington University School of Medicine, St. Louis, Missouri
63110
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ABSTRACT |
Recent studies suggest that the degree of mitochondrial dysfunction
in cerebral ischemia may be an important determinant of the final
extent of tissue injury. Although loss of mitochondrial membrane
potential ( m), one index of mitochondrial
dysfunction, has been documented in neurons exposed to ischemic
conditions, it is not yet known whether astrocytes, which are
relatively resistant to ischemic injury, experience changes in
m under similar conditions. To address this,
we exposed cortical astrocytes cultured alone or with neurons to
oxygen-glucose deprivation (OGD) and monitored
m using tetramethylrhodamine ethyl ester. Both neurons and astrocytes exhibited profound loss of
m after 45-60 min of OGD. However, although
this exposure is lethal to nearly all neurons, it is hours less than
that needed to kill astrocytes. Astrocyte m
was rescued during OGD by cyclosporin A, a permeability transition
pore blocker, and GN-nitro-arginine,
a nitric oxide synthase inhibitor. Loss of mitochondrial membrane
potential in astrocytes was not accompanied by depolarization of the
plasma membrane. Recovery of astrocyte m
after reintroduction of O2 and glucose occurred over a
surprisingly long period (>1 hr), suggesting that OGD caused specific,
reversible changes in astrocyte mitochondrial physiology beyond the
simple lack of O2 and glucose. Decreased
m was associated with a cyclosporin
A-sensitive loss of cytochrome c but not with activation of caspase-3
or caspase-9. Our data suggest that astrocyte mitochondrial depolarization could be a previously unrecognized event early in
ischemia and that strategies that target the mitochondrial component of
ischemic injury may benefit astrocytes as well as neurons.
Key words:
tetramethylrhodamine ethyl ester; mitochondrial
permeability transition pore; nitric oxide synthase; cyclosporin A; confocal microscopy; cortical cell cultures
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INTRODUCTION |
Mitochondrial dysfunction is an
early feature in nervous system ischemia. Functional studies on
mitochondria isolated from ischemic brain (Sims et al., 1986 ; Sims,
1991) and metabolic imaging studies of brain during ischemia (Watanabe
et al., 1994; Shiino et al., 1998; McCleary et al., 1999; Shadid et
al., 1999) indicate that brief periods of ischemia result in transient
mitochondrial respiratory defects that normalize rapidly after
reperfusion (Schutz et al., 1973; Hillered et al., 1984; Sims et al.,
1986). Longer periods of ischemia, however, result in a secondary,
irreversible decline in mitochondrial function that occurs minutes to
hours later (for review, see Siesjo et al., 1999). Although
mitochondrial failure is associated with loss of mitochondrial membrane
potential (m) in many injury conditions
(Green and Reed, 1998), it is not yet known whether impaired
mitochondrial respiration during cerebral ischemia is accompanied by
loss of m, because of the lack of sensitive
and specific probes for m in the intact
brain. Suggestive evidence comes from reports by Fujimura et al.
(1998), Andreyev et al. (1998), and Perez-Pinzon et al. (1999), who
observed release of cytochrome c from mitochondria rapidly after
reperfusion, and from a study by Krajewski et al. (1999), who observed
release of caspase-9, an intramitochondrial caspase, after global
ischemia. In addition, loss of m has been
directly demonstrated in hippocampal CA1 neurons exposed to
oxygen-glucose deprivation (OGD) by the use of acute brain slice
preparations (Bahar et al., 2000; Quick and Dugan, 2000).
The selective vulnerability of neurons to ischemic injury has been
taken as an indication that neurons experience greater metabolic
deterioration than do astrocytes, which are generally spared by the
same ischemic insult. Furthermore, astrocytes contain glycogen stores
that might be expected to buffer metabolic insults and help maintain
mitochondrial function during ischemia. Extensive data indicate that
astrocytes are critically involved in a number of processes that affect
neuronal survival, such as glutamate uptake, maintenance of
extracellular pH and potassium, Ca2+
buffering, and transfer of lactate and/or pyruvate to neurons as energy
substrates (Magistretti et al., 1993; Forsyth, 1996; Vernadakis, 1996;
Anderson and Swanson, 2000; Walz, 2000). A number of these
astrocyte-support functions are dependent on mitochondrial membrane
potential, and many of these same functions are impaired early in the
ischemic period (Benveniste et al., 1984; Montgomery, 1994; Juurlink,
1997). This led us to speculate that deterioration of astrocyte
mitochondrial function, specifically loss of
m, might occur quite early in ischemia.
In the present study we found that astrocytes experience early and
pronounced, but reversible, loss of mitochondrial membrane potential in
response to oxygen-glucose deprivation, which does not result in
astrocyte cell death. We characterized the time course and pharmacology
of astrocyte mitochondrial depolarization and looked at specific
biochemical events related to the loss of astrocyte
m induced by OGD. Our data suggest that decreased m in astrocytes during ischemia
could contribute to the cascade of events leading to ischemic cell death.
Parts of this paper have been published previously in abstract
form (Reichert et al., 2000).
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MATERIALS AND METHODS |
Reagents. Tetramethylrhodamine ethyl ester (TMRE),
5,5',6,6'-tetrachloro-1,1',3,3'-tetraethylbenzimidazolocarbocyanine
iodide (JC-1), rhodamine 123, bis-(1,3-dibutylbarbituric
acid)trimethine oxonol [DiBAC4(3)], and propidium iodide (PI) were
purchased from Molecular Probes (Eugene, OR). FK506 (tacrolimus) was
purchased from Boehringer Mannheim (Indianapolis, IN), and
cyclosporin A (CsA) was purchased from Sigma (St. Louis,
MO) or Calbiochem (La Jolla, CA). MK-801 and
2,3-dihydroxy-6-nitro-7-sulfamoyl-benzo(F)quinaoxaline (NBQX) were
obtained from Research Biochemicals (Natick, MA), and
GN-nitro-arginine, oligomycin,
carbonyl cyanide
p-(trifluoromethoxy)phenylhydrazone (FCCP), and
rotenone came from Sigma. Minimal Essential Medium without glutamine
was purchased from Life Technologies (11430-022; Gaithersburg, MD).
Other reagents were obtained from standard suppliers.
Cortical cell cultures. Cortical astrocyte cultures and
mixed cortical neuron astrocyte cocultures were prepared as described previously (Dugan et al., 1995a). Astrocyte cultures were prepared from
postnatal day 0 (P0) to P3 mouse pups by plating cortical cell
suspensions on Primaria (Falcon) 75 cm2
flasks or 35 mm coverslip dishes (Mat-Tek) coated previously with
poly-D-lysine and laminin. Mixed
neuron-astrocyte cultures were prepared from fetal (embryonic day 15)
Swiss-Webster mice (Charles River Laboratories, Wilmington, MA) by
plating cortical cell suspensions onto a confluent bed of astrocytes.
Cultures were treated with Ara-C (10 µM) 5-6 d
after plating to inhibit proliferation of oligodendroglia and
microglia. Cultures were fed biweekly with growth medium (Minimal
Essential Medium plus 20 mM glucose, 26.2 mM NaHCO3, 10% horse
serum, and 2 mM
L-glutamine), until the final feeding at day 11 or 12 in vitro, when the medium was exchanged with Minimal
Essential Medium supplemented with 2 mM
L-glutamine. Astrocytes and mixed cultures were
used for experiments ~15 d after plating.
Oxygen-glucose deprivation. Combined oxygen-glucose
deprivation was performed as described previously (Goldberg and Choi, 1993). Briefly, cells were placed in an anaerobic (<0.02%
O2 and 5% CO2)
environmental chamber (Forma Scientific), and the culture medium was
exchanged with oxygenated, glucose-containing solution (for controls)
or deoxygenated, glucose-free medium (for OGD groups). TMRE (100 nM) and all treatment drugs were included with
the final medium exchange, i.e., at the onset of OGD. Control cultures
were sealed immediately after the final exchange to retain
O2 in the culture medium by placing a lid lined
with Vaseline on the culture dish. OGD dishes were left unsealed. All
cultures were then placed in the 37°C incubator within the anaerobic
chamber for the duration of the experiment. OGD dishes were
subsequently sealed with Vaseline at the end of the deprivation period.
To study the role of nitric oxide synthase (NOS) in mitochondrial
depolarization, cells were pretreated with
GN-nitro-arginine (1 mM) for 4 hr, and then
GN-nitro-arginine (1 mM) was reapplied at the beginning of OGD. To
determine the number of neurons and astrocytes killed by exposure to
oxygen-glucose deprivation, propidium iodide (50 µg/ml final concentration) was added to cultures 24 hr after OGD, and the propidium
iodide-positive astrocytes and neurons were counted using confocal
microscopy to differentiate the cell layers.
Fluorescence imaging of mitochondrial membrane potential. To
evaluate how TMRE fluorescence responded to changes in
m in cortical astrocytes, cultures loaded
with TMRE (100 nM) were exposed to
mitochondrial-depolarizing agents including the complex I inhibitor
rotenone (30 µM), rotenone plus the
F0F1-ATPase inhibitor oligomycin (2.5 µg/ml), and the mitochondrial uncoupler FCCP (10 µM). TMRE fluorescence [excitation  (Ex
) of 568 nm and emission (Em ) > 590 nm] in
mitochondria was visualized on a confocal microscope (Noran Odyssey)
equipped with a krypton-argon laser (488 and 568 nm emission lines),
using a 40×, 1.4 numerical aperture Plan Apo oil-immersion objective
(Nikon). To minimize photobleaching and other free radical dye
reactions, laser intensity was minimized. To allow analysis of
mitochondrial membrane potential in cultures during OGD, cultures were
loaded with TMRE (100 nM) at the onset of OGD,
culture dishes were then sealed with Vaseline before removal from the
anaerobic chamber, and TMRE fluorescence in astrocyte mitochondria was
assessed. Several fields per dish were selected at random by
phase-contrast optics, and then fluorescence images were captured using
MetaMorph imaging and analysis software. Fluorescence images were
digitized at 640 × 480 pixels. Mitochondrial TMRE fluorescence
was analyzed in images after background fluorescence was subtracted,
using a mask function to eliminate nonmitochondrial pixels (determined
as the background fluorescence in the cell nuclei). The average
mitochondrial TMRE pixel intensity for each cell was then determined.
JC-1 fluorescence was evaluated at Ex of 488 nm and Em > 525 nm (monomer) and Ex of 488 nm and Em > 590 nm
(J-aggregates). Rhodamine 123 settings were Ex of 488 nm and Em
> 515 nm. Imaging protocols similar to that described for
TMRE were used for these dyes. Astrocyte plasma membrane potential was
imaged by confocal microscopy using DiBAC4(3) (1 µM; excitation = 488 nm; emission
= 515 nm) at the end of OGD.
Determination of cytochrome c release. Pure astrocyte
cultures were exposed to OGD for 90-120 min until mitochondrial
depolarization was observed in a sister culture used solely to monitor
m. Astrocyte mitochondria were then isolated
using a modification of the method described by Almeida and Medina
(1997). Purity of the mitochondrial fraction was confirmed by assaying
the enrichment in cytochrome oxidase activity (data not shown). Cells
were washed with PBS, pH 7.4, harvested, and centrifuged at
700 × g for 5 min. The pellet was resuspended in
isolation buffer (320 mM sucrose, 10 mM Tris-HCl, pH 7.2, and 1 mM EDTA-K+) and
homogenized. Homogenates were centrifuged at 1500 × g
for 5 min twice. Supernatants collected from both centrifugations were
centrifuged at 17,000 × g for 10 min at 4°C. The
pellet (mitochondrial fraction) was resuspended in 200-300 µl of
isolation buffer. The supernatant was further centrifuged at
200,000 × g for 30 min at 4°C to remove membranes.
Cytochrome c was quantified in the mitochondrial and cytoplasmic
fractions using a Quantikine M cytochrome c ELISA kit from R & D
systems (Minneapolis, MN). A standard curve for cytochrome c was
constructed using standards included in the kit. Because we expected
relatively low concentrations of cytochrome c in the cytosol and wanted
to increase our sensitivity for changes in cytosolic cytochrome c, the
amount of protein analyzed for cytochrome c content in the cytosolic
fractions was 2.5 times that of the mitochondrial fractions. The amount
of protein per sample was determined using the BCA assay system
(Pierce, Rockford, IL), and the concentration of cytochrome c was
expressed as micrograms per milligram of protein.
Analysis of caspase-3 and caspase-9 activity. To assay
caspase-3 and caspase-9 activity after OGD, astrocyte cultures grown in
100 mm dishes were exposed to 90-120 min of OGD or control conditions
and harvested; some cultures were exposed to OGD and then returned to
medium containing O2 and glucose for 1 hr before harvesting. Cells were washed twice with cold PBS, and after the final
wash, 5 ml of cold PBS was added to each dish, and the cells were
scraped and transferred to a 15 ml centrifuge tube for each sample. To
rinse the dishes, 3 ml of cold PBS was used and added to the 15 ml
tubes. Tubes were centrifuged at 2500 rpm for 10 min. The PBS was
discarded, and the pellet was frozen at  80°C until use. Caspase-3
activity was assayed using an EnzChek Caspase-3 Assay Kit (Molecular
Probes) as per the assay kit instructions. The assay plate was
incubated for 30 min at room temperature, and fluorescence from
cleavage of the substrate (Z-DEVD-R110) was measured on a microplate
fluorescent reader (FL600, Bio-Tek), using excitation = 490 nm
and emission = 520 nm.
Caspase-9 activity was determined using a mammalian ced-3 homolog
6/Caspase-9 Fluorometric Protease Assay Kit (Chemicon, Temecula, CA) as per the manufacturer's instructions. Cells were lysed in the
lysis buffer included in the kit and then incubated on ice for 10 min.
Fifty microliters of each sample were added to a microtiter plate,
followed by addition of 2× reaction buffer containing 10 mM DTT to each sample. Finally,
Leu-Glu-(oMe)-His-Asp(oMe)-7-amino-4-trifluoromethyl coumarin
substrate was added, and the plate was incubated at 37°C for 1-2 hr.
Fluorescence was read on a fluorescence microplate reader, using
emission = 400 nm and emission = 505 nm.
Caspase-appropriate inhibitors (included with each kit) were used to
allow nonspecific cleavage of the fluorescent substrates to be subtracted.
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RESULTS |
Oxygen-glucose deprivation results in profound loss of astrocyte
mitochondrial
We used the potentiometric fluorescent compound TMRE to
monitor astrocyte m. Both
tetramethylrhodamine methyl ester (TMRM) and TMRE have been used to
measure m (Andreyev et al., 1998; Bindokas et
al., 1998), but it has become clear that their fluorescence response to
mitochondrial depolarization differs considerably depending on the
concentration of the probe used and to some extent on the relationship
of the plasma membrane and mitochondrial membrane potentials (Ward et
al., 2000). We therefore set out to establish optimal conditions for
the use of TMRE in cortical astrocytes. Using TMRE at 100 nM, we observed a reproducible, graded, and
time-dependent decrease in fluorescence after mitochondrial
depolarization produced by rotenone, rotenone plus oligomycin, or FCCP
(Fig. 1). Concentrations of TMRE >100 nM demonstrated fluorescence unquenching and
increased fluorescence with mitochondrial depolarization, and
concentrations lower than ~50 nM produced
insufficient fluorescence to detect sensitively changes in
m without increasing laser intensity and subsequent phototoxicity. Although Ward et al. (2000) reported unquenching-mediated increases in fluorescence for TMRM at 100 nM, we failed to observe unquenching with this
concentration of TMRE, possibly reflecting greater binding of TMRE to
the mitochondrial matrix (Scaduto and Grotyohann, 1999) or unquenching
that was more rapid than our earliest time point with FCCP (60 sec).
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Figure 1.
Mitochondrial depolarization results in a graded
decline in TMRE fluorescence in astrocytes. Astrocytes were loaded with
TMRE (100 nM) and exposed to the mitochondrial depolarizing
agents rotenone (complex I inhibitor), rotenone plus oligomycin
(F0F1-ATPase inhibitor), and FCCP
(mitochondrial protonophore). TMRE fluorescence, reflecting
mitochondrial membrane potential, was visualized by confocal
microscopy. TMRE fluorescence decreased after rapid depolarization by
FCCP or gradual depolarization by rotenone or rotenone plus oligomycin.
Panels are pseudocolor representations of TMRE
fluorescence intensity (scale on right). Scale bar, 20 µm. Olig, Oligomycin; Rot,
rotenone.
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We then used TMRE to evaluate m in cortical
cultures exposed to OGD. Mixed cultures were exposed to OGD for periods ranging from 30 to 90 min in the presence of TMRE, and
m was assessed in neurons and the underlying
astrocytes using confocal microscopy. Exposure to 30 min of OGD had no
effect on astrocyte or neuronal m, but 40-60
min of OGD produced a progressive decline in astrocyte
m, with near-complete loss of
m by 60 min of OGD (Fig.
2A,B). Neuronal
mitochondria were also uniformly depolarized by 60 min of OGD but
demonstrated a more variable loss of m
between 40 and 60 min of OGD, with depolarization generally, but not
always, preceding the loss of m in astrocytes
(data not shown). Using DiBAC4(3) to monitor
astrocyte plasma membrane potential, we observed no change in plasma
membrane potential after OGD (Fig. 3).
Therefore, decreased TMRE fluorescence appears to reflect only changes
in mitochondrial m in these experiments.
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Figure 2.
Mitochondrial membrane potential in cortical
astrocytes exposed to OGD and subsequent reintroduction of oxygen and
glucose. Mixed cortical cultures were exposed to OGD in the presence of
the potentiometric dye TMRE. A, C, Mitochondrial , as
TMRE fluorescence, was evaluated in the astrocyte monolayer by confocal
microscopy after 40, 50, or 60 min of OGD (A) or
during recovery after reintroduction of oxygen and glucose after 60 min
of OGD (C). Control cultures were maintained in
21% oxygen and 5.5 mM glucose for 60 min. B,
D, The time course of mitochondrial TMRE fluorescence loss in
astrocytes during OGD (B) and the recovery of
mitochondrial after readdition of oxygen and glucose
(D) are shown. Dashed line in
B indicates interpolation of TMRE fluorescence changes
between 0 and 40 min. Values are mean TMRE fluorescence intensity (as
% of control) ± SEM; n > 100 for all
conditions from 3 or more independent experiments. *p < 0.05 by ANOVA and Tukey's post hoc analysis.
E, Astrocytes were exposed to OGD (60 min) or OGD
followed by reintroduction of oxygen plus glucose for an additional 60 or 120 min. Alterations in mitochondrial morphology, visualized by TMRE
fluorescence, were apparent after OGD, persisted after reintroduction
of O2 plus glucose for 60 min, but had resolved by 120 min
after addition of O2 plus glucose. Scale bar: A,
C, 20 µm. CTRL, Control; Rep,
reperfusion.
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Figure 3.
Plasma membrane potential in astrocytes exposed to
low K+ (1 mEq K), high
K+ (30 mEq K), control, and
OGD conditions (90-120 min) in the presence of DiBAC4(3) (1 µM), a plasma membrane potentiometric dye. Control
cultures were maintained in 21% oxygen and 5.5 mM glucose
for 90-120 min. A, DiBAC4(3) fluorescence was
visualized by confocal microscopy (excitation = 488 nm,
emission = 515 nm) at the end of OGD. B, There
was no change in plasma membrane potential in astrocytes exposed to OGD
compared with the control condition.
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We confirmed OGD-induced loss of m with two
other potentiometric dyes, JC-1 and rhodamine 123. Experiments with JC-1, a highly sensitive ratiometric probe for
m, confirmed our observations with TMRE (data
not shown). However, we found that JC-1 was less reliable than TMRE for
our specific studies because, at the extremely low levels of
m that we observed, both JC-1 aggregates and
monomers are lost from mitochondria, giving artifactually high
fluorescence ratios. Similar observations were made with rhodamine 123, but because of the prominent unquenching properties of this probe, we
chose to use TMRE for subsequent experiments.
Loss of astrocyte m during
OGD is blocked by inhibition of the mitochondrial permeability
transition pore and NOS
We next determined the pharmacology of astrocyte mitochondrial
depolarization. Cyclosporin A, an inhibitor of both calcineurin and the
mitochondrial membrane permeability transition pore (mPTP), partially
prevented the loss of astrocyte m (Table
1). However, FK506 (tacrolimus), which
inhibits calcineurin but not the mPTP (Connern and Halestrap, 1994),
failed to rescue m, suggesting that
activation of the mPTP contributes to the OGD-induced loss of
m. The general nitric oxide inhibitor
(GN-nitro-arginine) also
partially rescued astrocyte m. Protection by
combined treatment with CsA and the NOS inhibitor was not significantly
better than that with either agent alone. No effect of CsA or
GN-nitro-arginine on astrocyte
m under control conditions was observed
(Table 1). Neither the NMDA receptor antagonist MK-801 nor the
general AMPA/kainate receptor antagonist NBQX affected the
mitochondrial depolarization induced by OGD.
Recovery of astrocyte m after
reintroduction of oxygen and glucose after OGD is a delayed process
If mitochondrial depolarization during OGD reflects the simple
lack of glucose and oxygen, then readdition of the two metabolic substrates should allow rapid recovery of m.
However, we found that when O2 and glucose were
reintroduced to astrocytes after OGD, mitochondria required >1 hr to
return to control levels of m (Fig.
2C,D); mitochondrial membrane potential was still <50% of
control values 30 min after "reperfusion" (readdition of
O2 and glucose) and was still only 85% of
controls at 1 hr. However, mitochondrial membrane potential returned to
control values after an additional hour in O2 and glucose.
We also noted that the morphology of repolarized mitochondria often
appeared abnormal, even 1 hr after readdition of
O2 and glucose (Fig. 2E).
Mitochondria were not obviously swollen, but there seemed to be a
greater number of round "discrete" mitochondria with less
filament-like structures and fewer intramitochondrial connections.
These morphological changes also appeared to have resolved within 2-3
hr after reintroduction of O2 and glucose (Fig.
2E). Taken together, these data suggest that OGD
causes persistent (i.e., >1 hr) but reversible changes in astrocyte
mitochondrial function and structure that are not attributable solely
to lack of O2 and glucose.
Cytochrome c is lost from mitochondria during astrocyte
mitochondrial depolarization
Loss of m has been associated with
release of cytochrome c from mitochondria during the course of
apoptotic cell death in many cell types (Green and Reed, 1998).
However, it is unclear whether mitochondrial depolarization will lead
to release of cytochrome c in cells that are not destined to die. To
determine whether prolonged, but nonlethal (Fig.
4), mitochondrial depolarization in
astrocytes results in release of cytochrome c, we first confirmed that
astrocytes cultured without neurons would undergo mitochondrial depolarization in response to OGD. We found that, although astrocytes grown in pure culture exhibited slower loss of
m than did astrocytes cocultured with neurons
(Fig. 5), the ultimate magnitude of
m loss was similar whether astrocytes were cultured alone or with neurons. In addition, mitochondrial
depolarization in pure astrocyte cultures was partially blocked by
cyclosporin A (data not shown), mirroring our results in mixed
cultures.
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Figure 4.
Determination of astrocyte and neuronal death
after OGD in cortical cultures. Mixed cortical cultures were exposed to
OGD or control conditions for 60 min and then returned to normoxic,
glucose-containing solution for 24 hr (data not shown) or 48 hr. The
number of dead neurons and astrocytes was determined by staining with
propidium iodide, followed by confocal microscopy to allow stained
cells in the astrocyte layer (left) to be differentiated
from the neurons above (right). PI-positive astrocytes
per well in a 24-well culture plate were 35 ± 12 astrocytes in
OGD-exposed cultures and 33 ± 15 astrocytes in control cultures
(from 4 to 8 wells from 3 independent replications), both of which
exhibit <0.001% astrocyte death. Most neurons were dead 24 hr after
OGD. Scale bar, 50 µm.
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Figure 5.
Comparison of OGD-induced mitochondrial
depolarization in astrocytes cultured alone or cocultured with neurons.
A, TMRE mitochondrial fluorescence was evaluated after
60 min of OGD in astrocytes cocultured with neurons
(right) or after 60 and 90 min of OGD in astrocytes
grown alone (left). The optical sectioning ability of
the confocal allowed astrocyte mitochondrial fluorescence to be
differentiated from that of the overlying neurons in mixed cultures.
Astrocytes cultured alone showed delayed loss of
m compared with astrocytes cultured with
neurons. Scale bar, 20 µm. B, Quantitative analyses of
mitochondrial TMRE fluorescence in the two culture types are shown.
Values are mean TMRE fluorescence intensity (% of control) ± SEM; n > 50 cells from 3 independent experiments.
In B, the dashed line represents interpolation of
TMRE fluorescence in astrocytes between 0 and 60 min.
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To determine whether prolonged mPTP-dependent loss of
m would lead to translocation of cytochrome c
in astrocytes exposed to OGD (cells that are not in the process of
dying), we measured cytochrome c content in the mitochondria and
cytosol. Using a "sentinel" culture loaded with TMRE to monitor
m, we then exposed pure astrocyte cultures to
OGD until m loss was observed. After
mitochondrial depolarization was documented, astrocytes were harvested,
and subcellular fractions were prepared. OGD caused a significant
decrease in mitochondrial cytochrome c content that was blocked by
treatment with CsA (Fig.
6A). CsA did not
significantly affect cytochrome c content in control cultures. Levels
of cytochrome c in the cytosol at baseline were quite low, and no
significant increase in cytosolic cytochrome c was observed after OGD
(Fig. 6A). To determine whether cytochrome c loss
from mitochondria continued to increase after reperfusion, cytochrome c
was measured in astrocyte cultures that had been returned to normoxic
glucose-containing medium for 1 hr after exposure to OGD for 60 min. We
found that mitochondrial cytochrome c still trended toward lower values
than did controls even 1 hr after readdition of
O2 and glucose but showed greater variability at this time point than at the end of OGD. Regardless, these data indicate
that extensive further release of mitochondrial cytochrome c after
reintroduction of O2 and glucose does not occur.
To observe cytochrome c release in astrocytes undergoing apoptosis,
astrocytes were treated with 0.2 µM
staurosporine for 16 hr (Fig. 6B). Cytochrome c
levels in mitochondria in staurosporine-treated cells were lower than
those in control astrocyte cultures.
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Figure 6.
Cytochrome c loss from depolarized astrocyte
mitochondria after OGD. Astrocytes were exposed to 90-120 min of OGD.
A, After mitochondrial depolarization was observed,
mitochondrial and cytosolic fractions were prepared and assayed for
cytochrome c concentration. The left half of the graph
shows cytochrome c concentration (per milligram of protein) in the
mitochondrial fraction. The right half shows
cytochrome c concentration in the cytosol. Values are the mean ± SEM; n = 4 independent replications for control and
OGD only; 3 additional replications included CsA conditions
(*p < 0.05, significantly different from control,
and **p < 0.05, significantly different from OGD,
by ANOVA and Tukey's post hoc analysis).
B, Apoptosis in astrocyte cultures was initiated by
staurosporine at 0.2 µM. Cytochrome c was measured as
nanograms per milligram of protein as stated above. Mitochondrial
cytochrome c levels are lower in staurosporine-treated cells.
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Caspase-9 and caspase-3 are not activated despite cytochrome c
release in astrocytes after OGD
Historically, release of cytochrome c from mitochondria has been
associated with activation of caspase-9 and caspase-3 in in
vitro, cell culture, and in vivo systems (for review,
see Green and Reed, 1998). To determine whether loss of cytochrome c
would activate caspase-3 or caspase-9 in cells not proceeding toward death, we assayed the activity of these two caspases in OGD-exposed astrocytes using fluorogenic substrates. No activation of either caspase was observed in astrocytes after exposure to OGD (Fig. 7). Activity levels in astrocytes exposed
to OGD showed a nonsignificant (p = 0.09)
trend toward lower values, whereas we easily detected increased
caspase-3 and caspase-9 activity in astrocyte cultures induced to
undergo apoptosis by treatment with staurosporine (Fig. 7). To
determine whether caspase-3 activation might be delayed after
cytochrome c was released during OGD, we measured caspase-3 activity 1 and 2 hr after reperfusion but found no increase in caspase-3 activity
at these later time points either (data not shown). Thus, although
exposure to OGD results in release of cytochrome c from astrocyte
mitochondria, activation of caspase-3 and caspase-9 is not
initiated.
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Figure 7.
Activity of caspase-3 and caspase-9 in astrocytes
exposed to OGD. Astrocytes were exposed to 90-120 min of OGD until
mitochondrial depolarization was confirmed, and then astrocytes were
harvested and assayed for caspase-9 (A) or
caspase-3 (B) activity (% control) using
fluorogenic substrates. No activation of either caspase was observed in
astrocytes exposed to OGD. In contrast, caspase-3 and caspase-9
activation was easily observed in astrocytes undergoing apoptosis
initiated by staurosporine at 0.2 µM. Values are the
mean ± SEM. Error bars for astrocytes exposed to staurosporine
and Boc-Asp(oMe)-CH2F (BAF) in
A and B are not visible.
Stauro, staurosporine.
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DISCUSSION |
This paper describes three novel findings. First, astrocytes
exposed to a relatively brief period of oxygen-glucose deprivation experience profound and prolonged mitochondrial depolarization that is
not associated with subsequent cell death. Neurons appear to accelerate
this process. To our knowledge, this is one of a handful of reports
indicating that nontransformed cells can experience an extended
duration of mitochondrial depolarization without overt injury or death.
We also found that loss of astrocyte m during
OGD was mediated, in part, by opening of the mPTP and by NOS activity,
providing the first direct evidence that the mPTP may contribute to
astrocyte mitochondrial dysfunction under conditions of energy
deprivation, suggesting that neuroprotection observed with CsA in CNS
ischemia might reflect actions on astrocytes as well as neurons.
Finally, we demonstrate that mitochondrial depolarization is
accompanied by loss of cytochrome c from mitochondria without subsequent activation of caspase-3 and caspase-9. These data support the idea that astrocyte mitochondrial dysfunction may be an early feature of ischemia, despite the relative invulnerability of astrocytes to ischemic injury.
Using OGD in cortical cell cultures to model many of the metabolic
aspects of ischemia, we found that astrocytes and neurons experience
early mitochondrial depolarization, beginning 45 min after the onset of
OGD and progressing to near-complete depolarization by 60 min of OGD.
This 15-20 min period corresponds to the time window during which
extracellular glutamate levels begin to rise and irreversible neuronal
injury is initiated in this model (Goldberg and Choi, 1993; Bruno et
al., 1994). However, injury to cortical neurons exposed to OGD is
excitotoxic and mediated via NMDA receptors (Goldberg and Choi, 1993),
and NMDA receptor activation can cause loss of
m in the absence of OGD (Dugan et al., 1995b; Nieminen et al., 1996; Schinder et al., 1996; White and Reynolds, 1996). Mitochondrial depolarization in neurons during OGD may simply
reflect this excitotoxic component of injury. In contrast, astrocytes
are not injured by this duration of OGD; astrocyte death is not
initiated until OGD is extended to 4 hr (Goldberg and Choi, 1993).
Mitochondrial depolarization in astrocytes precedes substantial loss of
ATP. As reported previously, ATP levels were still 70% of control
levels in cortical cultures exposed to 60 min of OGD (Bruno et al.,
1994). Most of this ATP loss was likely to reflect energy depletion in
neurons, rather than astrocytes, because neurons experienced collapse
of their plasma membrane potential by 60 min of OGD, whereas astrocytes
maintain their plasma membrane potential and tolerate an additional
2-3 hr of OGD without injury. Moreover, in the absence of OGD,
astrocytes are clearly capable of using ATP to maintain
m, running the
F0F1-ATPase "in
reverse" to support m. Inhibition of
electron entry via complex I by rotenone caused only a minimal decrease
in astrocyte m (Fig.
1), whereas coapplication of rotenone and the F0F1-ATPase inhibitor
oligomycin resulted in pronounced mitochondrial depolarization. Why
astrocytes fail to use this compensatory mechanism during OGD is
unclear, but taken together, these data raise the question of why
astrocytes experience such early mitochondrial depolarization during
OGD and whether neurons might, in fact, signal to astrocytes to
initiate mitochondrial depolarization. This idea is supported by a
growing body of literature describing extensive communication between
neurons and astrocytes (Kimelberg and Norenberg, 1989; Magistretti et
al., 1993; Giaume and McCarthy, 1996) and by our observation that
astrocytes exposed to OGD in the absence of neurons required nearly
twice as long to experience loss of m.
Further studies will explore the possibility that communication between
neurons and astrocytes is involved in early changes in astrocyte
mitochondrial function during OGD.
Loss of astrocyte m during OGD involved the
mPTP, a voltage-gated channel that allows molecules and ions
with a mass of <1500 Da to pass through the mitochondrial membrane.
Activation of the mPTP can lead to mitochondrial depolarization and in
certain cell types to release of cytochrome c from mitochondria
(Halestrap et al., 2000). Assembly of the mPTP is triggered by several
stimuli, including fatty acids, accumulation of mitochondrial calcium, and oxidative stress, events that occur during ischemia-reperfusion injury. In astrocytes exposed to OGD, m was
partly rescued by cyclosporin A. Inhibition of NOS also helped to
maintain m during OGD, implicating
NO/peroxynitrite in astrocyte mitochondrial depolarization. Cortical
astrocytes have little inducible NOS (iNOS) expression at
baseline, although they can be stimulated to express iNOS by cytokines
(Hewett et al., 1994). Mitochondrial NOS (Giulivi et al., 1998) in
astrocytes has not been definitively established because of the lack of
specific probes for this nitric oxide-generating system. Both nitric
oxide and peroxynitrite can inhibit mitochondrial metabolism and
respiration at a number of points in the metabolic machinery (Brown and
Borutaite, 1999). However, the combination of
GN-nitro-arginine and CsA was
not significantly more effective than either agent alone, suggesting
that peroxynitrite may be acting via opening of the mPTP to cause
astrocyte mitochondrial depolarization (Scarlett et al., 1996).
Additional processes, such as activation of mitochondrial-uncoupling
proteins, may contribute to mitochondrial depolarization. Involvement
of glutamate receptor-mediated calcium entry and direct uncoupling by
Ca2+ are unlikely because the AMPA/kainate
receptor antagonist NBQX had no effect on m loss.
Numerous studies have shown that mitochondrial depolarization is linked
to translocation of cytochrome c from mitochondria to the cytosol (see
Green and Reed, 1998). However, this association is not universal
(Bossy-Wetzel et al., 1998; Krohn et al., 1999) and has been studied
primarily in cells undergoing apoptotic death. Activation of the mPTP
can also initiate release of cytochrome c from mitochondria (Halestrap
et al., 2000). We observed a 20% loss of cytochrome c from
mitochondria at the end of OGD that was partly blocked by CsA,
suggesting involvement of the mPTP. Release of cytochrome c was not
accompanied by activation of either caspase-9 or caspase-3, suggesting
that cytochrome c was blocked from activating procaspase-9.
Surprisingly, loss of cytochrome c from mitochondria was not
accompanied by significant accumulation in the cytoplasm. We speculate
that this reflects rapid modification and/or degradation of cytochrome
c after its release, as has been proposed previously (Neame et al.,
1998; Putcha et al., 2000). In the latter study, release of cytochrome
c was sufficient to activate caspase-3 but did not result in a
detectable increase in cytoplasmic cytochrome c at any time point. The
mechanism(s) by which cytochrome c is cleared from the cytosol after
release from mitochondria remains to be determined. Studies on purified cytochrome c have shown that the oxidation state of the cytochrome (Wang and Kallenbach, 1998) and the interaction of the protein with
anionic lipids (deJhong et al., 1995) can enhance its susceptibility to
proteolysis, but whether either of these factors contributes to removal
of cytochrome c from the cytoplasm will need to be established.
Regardless, determining how cells terminate such potentially
proapoptotic signals is likely to be an important area for future study.
Loss of mitochondrial m during OGD produced
persistent but reversible changes in astrocyte mitochondrial structure and function. Although m eventually recovered
to control levels, normalization required more than an hour, suggesting
persistent inhibition of the electron transport chain or loss of
critical metabolic intermediates, such as adenine nucleotides (Sims,
1991). Ultrastructural changes in mitochondria including swelling and a
decrease in the syncytial nature of astrocyte mitochondria were observed after OGD plus reperfusion and required ~2 hr to reverse. These ultrastructural changes after OGD plus reperfusion may correspond to the mitochondrial swelling and matrix alterations reported in early
postischemic brain by electron microscopy (Petito and Babiak, 1982),
suggesting that derangements in mitochondrial function during ischemia
may occur in both astrocytes and neurons.
Depolarization of astrocyte mitochondria during OGD might have both
beneficial and harmful effects on neuronal survival. Short-term loss of
m would allow astrocytes to shift use of
glycogen and glucose temporarily away from aerobic metabolism to
glycolysis, increasing the amount of lactate available for delivery to
metabolically impaired neurons. This might be tolerated for as long as
astrocyte glycogen stores were available. However, prolonged loss of
m in astrocytes might be expected to have
injury-promoting effects during CNS ischemia. Astrocytes are involved
in the normal maintenance of brain homeostasis, including several
energy-dependent functions necessary for normal neuronal activity,
e.g., regulation of extracellular K+, pH,
and osmolality, export of metabolic intermediates, and rapid uptake of
neurotransmitters (Kimelberg and Norenberg, 1989; Magistretti et al.,
1993; Walz, 2000). The ability of astrocytes to maintain these
functions may, in fact, be a critical determinant of neuronal survival
after ischemia (Juurlink, 1997; Stanimirovic et al., 1997; Aschner et
al., 1999; Marrif and Juurlink, 1999). Loss of m and eventual energy failure in astrocytes
might lead to an inability to provide these critical support functions
during ischemia, thus exacerbating ischemic injury to neurons.
In summary, our data suggest that astrocyte mitochondrial dysfunction
may be a relatively unexplored but important early step in the cascade
of events involved in ischemic injury. In light of recent studies
showing neuroprotection by CsA in in vivo models of ischemia
(Siesjo et al., 1999), our data indicate that astrocytes, in addition
to neurons, might be therapeutic targets of CsA neuroprotection. In
addition, in agreement with studies suggesting that astrocytes may be
as vulnerable as neurons to ischemic injury in certain brain regions,
we speculate that astrocyte mitochondrial depolarization might
contribute to astrocyte death during ischemia. Finally, astrocytes
exposed to OGD may provide a model system in which to study aspects of
mitochondrial dysfunction that are not specifically involved in cell death.
| |
FOOTNOTES |
Received April 10, 2001; revised May 31, 2001; accepted June 13, 2001.
This work was supported by National Institutes of Health Grant NS 32636 (L.L.D.).
S.A.R. and J.S.K.-H. contributed equally to this work.
Correspondence should be addressed to Dr. Laura L. Dugan, Department of
Neurology, 660 South Euclid Avenue (Box 8111), Washington University
School of Medicine, St. Louis, MO 63110. E-mail:
duganl{at}neuro.wustl.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
at the end of OGD
