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The Journal of Neuroscience, November 15, 2000, 20(22):8229-8237
Limitations of Cyclosporin A Inhibition of the Permeability
Transition in CNS Mitochondria
Nickolay
Brustovetsky and
Janet M.
Dubinsky
Department of Neuroscience, University of Minnesota, Minneapolis,
Minnesota 55455
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ABSTRACT |
Activation of the mitochondrial permeability transition may
contribute to excitotoxic neuronal death (Ankarcrona et al., 1996 ; Dubinsky and Levi, 1998). However, cyclosporin A (CsA), a potent inhibitor of the permeability transition in liver mitochondria, only
protects against neuronal injury by limited doses of glutamate and
selected ischemic paradigms. The lack of consistent CsA inhibition of
the mitochondrial permeability transition was analyzed with the use of
isolated brain mitochondria. Changes in the permeability of the inner
mitochondrial membrane were evaluated by monitoring mitochondrial
membrane potential (  ), using the distribution of
tetraphenylphosphonium, and by monitoring mitochondrial swelling, using
light absorbance measurements. Metabolic impairments, large Ca2+ loads, omission of external
Mg2+, or low doses of palmitic acid or the
protonophore FCCP exacerbated Ca2+-induced sustained
depolarizations and swelling and eliminated CsA inhibition. BSA
restored CsA inhibition in mitochondria challenged with 50 µM Ca2+, but not with 100 µM Ca2+. CsA failed to prevent
Ca2+-induced depolarization or to repolarize
mitochondria when mitochondria were depolarized excessively.
Similarly, CsA failed to prevent mitochondrial swelling or PEG-induced
shrinkage after swelling when the Ca2+ challenge
produced a strong, sustained depolarization. Thus in brain mitochondria
CsA may be effective only as an inhibitor of the permeability
transition and the Ca2+-activated low permeability
state under conditions of partial depolarization. In contrast, ADP plus
oligomycin inhibited both permeabilities under all of the conditions
that were tested. In situ, the neuroprotective action of
CsA may be limited to glutamate challenges sufficiently toxic to induce
the permeability transition but not so severe that mitochondrial
depolarization exceeds threshold.
Key words:
permeability transition; cyclosporin A; excitotoxicity; mitochondria; neurodegeneration; cyclophilin
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INTRODUCTION |
Under high calcium loads or
oxidative stress a proteinaceous structure in the inner mitochondrial
membrane produces a mitochondrial permeability transition (mPT).
Functional properties of the mPT have been studied extensively in liver
and heart mitochondria (Bernardi et al., 1994; Zoratti and Szabo,
1995), but only recently has the mPT been characterized in neuronal
tissue (Kristal and Dubinsky, 1997; Andreyev et al., 1998; Dubinsky and
Levi, 1998; Brustovetsky and Dubinsky, 2000). We recently have
delineated conditions distinguishing both low and high permeability
states of mPT operation in brain mitochondria (Brustovetsky and
Dubinsky, 2000).
CsA is considered to be a potent inhibitor of the mPT as compared with
ADP and Mg2+, the next most effective
protective agents (Fournier et al., 1987; Crompton et al., 1988;
Broekemeier et al., 1989; Zoratti and Szabo, 1995). By interacting with
a mitochondrial cyclophilin, CsA may inhibit the mPT by preventing
cyclophilin association with the adenine nucleotide translocator or
other structure comprising the mPT pore (Halestrap and Davidson, 1990;
Nicolli et al., 1996). In liver and heart mitochondria CsA protection
depends on the magnitude of mitochondrial
Ca2+ loading (Bernardi et al., 1992) and
the presence of external Mg2+ (Novgorodov
et al., 1994). Accumulation of free fatty acids (FFA) accompanying mPT
induction by Ca2+ plus oxidants, but not
by Ca2+ plus phosphate, prevents mPT
closure by CsA in liver mitochondria (Broekemeier and Pfeiffer, 1995).
In heart mitochondria CsA and ADP act synergistically to inhibit the
mPT. The loss of endogenous adenine nucleotides accompanying the mPT
pore opening may explain the decreased effectiveness of CsA inhibition
(Novgorodov et al., 1992).
CsA has been used to identify activation of the mPT as a crucial factor
leading to cell death (Zamzami et al., 1996). The mPT remains closed
during cardiac ischemia but opens on reperfusion, causing mitochondrial
dysfunction (Griffiths and Halestrap, 1995). The mPT contributes to the
lethal injury of hepatocytes exposed to
tert-butylhydroperoxide (Nieminen et al., 1995). In brain, with abundant cyclophilin, CsA protection has been reported only for
hypoglycemia or ischemic insults in hyper- or hypoglycemic animals
(Folbergrova et al., 1997; Li et al., 1997; Friberg et al., 1998).
Although CsA neuroprotection has been attributed to calcineurin
inhibition (Dawson et al., 1993; Ankarcrona et al., 1996), CsA
ameliorates mitochondrial depolarization, suggesting mPT participation
in excitotoxicity (Nieminen et al., 1996; Schinder et al., 1996; White
and Reynolds, 1996; Vergun et al., 1999), yet the extent of CsA
neuroprotection has been limited and varies substantially for the doses
that have been tested to date.
The balance between modulators of the mPT,
Ca2+, Mg2+,
FFA, and adenine nucleotides may vary in brain cells in
situ, determining the relative vulnerability to injury and the
extent of possible CsA protection. We therefore tested CsA against a
range of glutamate challenges. We investigated the effects of these
modulators on CsA inhibition of both high and low permeability states
of the mPT in isolated brain mitochondria. We found that the extent of mitochondrial depolarization was associated with the ability of CsA to
prevent opening and to close the mPT pore, limiting the effectiveness
of CsA as a neuroprotective agent.
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MATERIALS AND METHODS |
Isolation of brain mitochondria. Brain mitochondria
were isolated as previously reported (Brustovetsky and Dubinsky, 2000). For measurement of mitochondrial swelling the brain mitochondria were
purified further on a discontinuous Percoll gradient to remove synaptosomes (Kristal and Dubinsky, 1997; Brustovetsky and Dubinsky, 2000).
Measurements of , mitochondrial swelling, and respiration.
Isolated brain mitochondrial experiments were performed in a medium containing (in mM) 215 mannitol, 50 sucrose, 3 KH2PO4, and 10 HEPES, pH
7.4, 320 mOsm and the indicated amount of substrate at 30°C in a
stirred 2.0 ml chamber. MgCl2 (0.5 mM) was present unless indicated otherwise.
Sucrose-mannitol medium was used in preference to KCl-based medium to
prevent contributions from K+ channel
activation to mitochondrial potential and volume (Garlid, 1996).
Although KCl medium would depolarize synaptosomes,
K+-stimulated synaptosomal
Ca2+ uptake also would diminish our
applied calcium challenges by an unspecified amount (Blaustein, 1975).
In preliminary experiments the purified brain mitochondria slowly lost
accumulated tetraphenylphosphonium (TPP+) in KCl medium, whereas mitochondria
in sucrose-mannitol-based medium maintained stable
TPP+ accumulations in excess of 30 min.
Because properties of liver mitochondria were altered after Percoll
purification (Litsky and Pfeiffer, 1997) in experiments monitoring
alone, unpurified mitochondria were used. Protein
concentration in the chamber was 1.0-1.5 mg/ml or 0.1-0.2 mg/ml for
unpurified or Percoll gradient-purified mitochondria, respectively, as
determined by the Bradford method (Bradford, 1976).
was followed with a TPP+-sensitive
electrode (Kamo et al., 1979; Brustovetsky and Dubinsky, 2000). For the
unpurified mitochondria the amount of TPP+
distributed into synaptosomes was determined by comparing the initial
[TPP+]o in
sucrose-mannitol medium (0.41 ± 0.03 µM,
mean ± SEM; n = 4) with that in an identical
medium containing 3 mM succinate plus 3 mM glutamate, with 125 mM
KCl substituted for the sucrose and mannitol (0.52 ± 0.02 µM; n = 5) for the addition of
equal volumes of the same mitochondrial preparation.
Ca2+-induced mitochondrial swelling,
reflecting the opening of a large permeability pathway of the mPT, was
followed spectrophotometrically (540 nm) at room temperature with a
Beckman DU7500 spectrophotometer (Brustovetsky and Dubinsky, 2000). For
simultaneous measurements the mitochondria were incubated at 30°C in
a continuously stirred 0.3 ml chamber equipped with both a miniature
TPP+ electrode and a photodiode light
detector in combination with a laser light source (670 nm; Andreyev and
Fiskum, 1999) through a light guide. Previous absorbance measurements
that were made by scanning 300-800 nm wavelengths yielded no
differences in responses at the different wavelengths (Kristal and
Dubinsky, 1997). For each of these last measurements purified
mitochondria were used because mitochondrial swelling was masked in the
presence of synaptosomes. All data traces are representative of at
least three replicates.
Oxygen consumption was measured with a miniature Clark-type electrode
in a closed chamber, simultaneous with
TPP+ measurements, as previously described
(Brustovetsky and Dubinsky, 2000).
Neuronal culture and toxicity experiments. Toxicity
experiments were performed on hippocampal cultures 12-15 d in
vitro, prepared from postnatal day 1 rat pups according to
established laboratory procedures (Dubinsky, 1993). Briefly, cultures
were exposed to glutamate in the range 10-500
µM for 5 min in serum-free supplemented MEM,
rinsed in Earle's basic salt solution, and incubated for 24 hr before
assessment of survival with the use of trypan blue exclusion, as
previously described (Dubinsky, 1993). Where indicated, the cultures
were pretreated with 1 µM CsA for 1 hr in
addition to the continuous presence of CsA during the 24 hr incubation period. Equal amounts of vehicle were present in all untreated controls.
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RESULTS |
CsA effects on glutamate excitotoxicity
In our experiments 1 µM CsA partially protected
neurons against 500 µM glutamate but failed to protect
neurons against injury induced by glutamate exposure over the entire
range of glutamate concentrations that were tested (Fig.
1). Although CsA appeared to shift the
average log ED50 of the glutamate dose-response
curve to higher concentrations, this failed to reach significance with continued repetitions [log ED50 of  3.50 ± 0.22 (n = 5) 315 µM for
glutamate plus CsA vs 3.83 ± 0.19 (n = 4) 150 µM for glutamate alone; p = 0.052, two-tailed t test]. Hill slopes were equally variable and not significantly different (1.5 ± 0.6 for
glutamate vs 1.3 ± 0.5 for glutamate plus CsA). If only the
cultures that were treated with 500 µM
glutamate were compared, however, a significant difference would be
detected [18.9 ± 1.6% survival (n = 39) from 14 experiments for glutamate alone vs 41.3 ± 1.7% survival
(n = 47) from 15 experiments for glutamate plus CsA;
p < 0.0001, two-tailed t test]. In
agreement with published reports (McDonald et al., 1996, 1997), higher
CsA concentrations were themselves toxic and therefore did not protect
against glutamate exposure. The inability of CsA to protect neurons
across a broad range of glutamate concentrations could be interpreted
to mean that the mPT is not involved in excitotoxicity. Alternately,
these data could reflect the possibility that CsA is not an effective
across-the-board inhibitor of the mPT.
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Figure 1.
Dose dependence of glutamate-induced neuronal
death in the absence and presence of 1 µM CsA. Data from
two representative experiments are shown. Log ED50,
ED50 concentration in µM, and Hill slopes for
the glutamate (Glu) and Glu plus CsA curves are 3.78,
166 µM, and 2.1 and 3.49, 321 µM, and
1.1, respectively. Data represent the mean ± SEM of three
replicates at each point.
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Characterization of the mPT in isolated CNS mitochondria
A high permeability pathway in the inner mitochondrial membrane,
the mPT, has been well characterized in liver mitochondria (Hunter and
Haworth, 1979a-c). The first indication of mPT pore substates
with a low permeability in liver mitochondria came from a comparison of
the time courses for the transmembrane equilibration of small solutes
after rapid pore opening (Pfeiffer et al., 1978). The low permeability
pathway has a low conductance and is selective for small ions (Riley
and Pfeiffer, 1985; Al-Nasser and Crompton, 1986; Broekemeier and
Pfeiffer, 1995; Broekemeier et al., 1998).
CNS mitochondria respond to Ca2+ by the
activation of both high and low permeability pathways in the inner
mitochondrial membrane (Brustovetsky and Dubinsky, 2000). In 3 mM succinate Ca2+ activates a
low permeability pathway that can be observed as a sustained
depolarization without mitochondrial swelling (Brustovetsky and
Dubinsky, 2000). In 3 mM succinate plus 3 mM
glutamate Ca2+ produces a transient
mitochondrial depolarization, rapid repolarization accompanied by
calcium uptake, and a slowly progressive secondary depolarization and
loss of accumulated Ca2+ accompanied by
swelling (Dubinsky et al., 1999; Brustovetsky and Dubinsky, 2000). This
later response characterizes the opening of the high permeability,
classical mPT pathway (Brustovetsky and Dubinsky, 2000). In an
intermediate substrate environment (10 mM succinate) a
combination of both responses may be evident. The time course and
amplitude of mitochondrial swelling also depend on the substrate
environment (Fig. 2A).
However, the maximal Ca2+-induced swelling
amounted to approximately one-half of that seen in response to the
addition of a nonspecific artificial channel former, alamethecin (Fig.
2B). The decreases in light scattering in response to
Ca2+ representing mitochondrial swelling
were reversed when mitochondria were incubated in iso-osmotic medium
containing high-molecular-weight polyethylene glycol (PEG; Fig.
3). Under these conditions PEG prevented
swelling presumably by plugging the pore (Pfeiffer et al., 1995), and
Ca2+-induced depolarization, possibly
associated with the low permeability pathway, was observed (Fig.
3B). Simultaneously, the substantial activation of
respiration by Ca2+ was not altered by
PEG. The observed light scattering increase may reflect hydroxyapatite
formation (Andreyev et al., 1998). In the absence of exogenous
substrates the increase in light scattering was diminished (Fig.
4A). This condition was
unlikely to be associated with appreciable
Ca2+ influx. The size of the
Ca2+-activated high permeability pore of
brain mitochondria was estimated by using differently sized PEG
molecules (Fig. 4A; Pfeiffer et al., 1995). As the
molecular weight (MW) of the PEG increased, the amplitude of swelling
decreased. Molecules of 1090 MW would correspond to 50% inhibition of
the high permeability mPT of brain mitochondria (Fig.
4B). The high permeability mPT was closed with the
chelation of Ca2+ by EGTA.
High-molecular-weight PEG addition after
Ca2+-induced mitochondrial swelling had
reached a steady state caused mitochondrial shrinkage (Fig.
5A). EGTA addition before PEG
prevented the shrinkage, indicating that chelation of
Ca2+ allowed the high permeability mPT to
close and prevented mannitol-sucrose efflux (Fig. 5B;
Haworth and Hunter, 1979).
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Figure 2.
The kinetics and amplitude of mitochondrial
swelling varied, depending on the magnitude of the
Ca2+ load (B) and the
substrates available for mitochondrial respiration
(A). Alamethecin (30 µg/ml) was added in
B (arrows) to induce maximal swelling of
the entire mitochondrial population.
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Figure 3.
High-molecular-weight PEG prevented the light
scattering decrease, but not the depolarization, produced by
Ca2+. Mitochondrial swelling (light scattering,
top trace) and membrane potential
(TPP+ electrode response, bottom
trace) were measured simultaneously in the presence
(B) or absence (A) of PEG
(MW 3350). A, Mitochondria were tested in the standard
medium while respiring on 3 mM succinate plus 3 mM glutamate, 310 mOsm. B, Mitochondria were
tested in a medium consisting of (in mM) 108 mannitol, 25 sucrose, 15 PEG (3350 MW), 10 KCl, 10 HEPES, 3 KH2PO4, 0.5 MgCl2, 3 succinate, and 3 glutamate, pH 7.4, 310 mOsm.
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Figure 4.
Sizing of the brain mPT pore by different
molecular weight PEGs. A,
Ca2+-activated decreases in light scattering traces
were prevented progressively in the presence of PEGs of increasing
molecular weights. Stock 300 mOsm solutions of the following PEG
concentrations were made in standard medium without any sucrose or
mannitol: PEG300, 227 mM; PEG600, 167 mM;
PEG1000, 118 mM; PEG1450, 87 mM; PEG3350, 45 mM; PEG8000, 20.4 mM. Of each stock 30% was
combined with 70% of the standard mannitol-sucrose medium to produce
the solutions that were used in this experiment (Pfeiffer et al.,
1995). The measurements were extended beyond the time period shown in
A until swelling reached the maximum value.
B, Mitochondrial swelling, expressed as a percentage of
the maximum observed in the absence of PEG, varied with PEG size.
Half-maximal swelling corresponded to a MW of 1090.
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Figure 5.
EGTA closed the brain mPT pore. A,
Light scattering decreases in response to Ca2+ were
reversed by the addition of PEG (3350 MW). B, The
addition of 1.5 mM EGTA before PEG prevented PEG-induced
mitochondrial shrinkage after steady-state pore opening by
Ca2+. In both A and B,
mitochondria were respiring on 3 mM succinate plus 3 mM glutamate. PEG (6.67%) was added to the standard
testing medium for a final osmolarity of 395 mOsm.
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CsA effects on the Ca2+-activated low
permeability pathway
Mitochondria were examined for the ability of CsA to prevent
opening or promote closure of both low and high permeability pathways.
TPP+ electrode measurements of
mitochondrial membrane potential were used to determine the ability of
CsA to close the Ca2+-activated low
permeability pathway. The addition of 50 µM
Ca2+ to mitochondria induced a sustained
depolarization (Fig. 6), characteristic
of the low permeability pathway (Brustovetsky and Dubinsky, 2000). CsA
restored , indicating an involvement of the mPT in the
Ca2+-induced depolarization. However, CsA
failed to restore after the stronger depolarization
induced by 100 µM
Ca2+, even at concentrations up to 6 µM. Added after CsA, ADP plus oligomycin, an
inhibitor of F1F0ATP
synthase, repolarized mitochondria. ADP plus oligomycin also
repolarized mitochondria in the absence of CsA (Brustovetsky and
Dubinsky, 2000). The ADP-induced repolarization was interpreted to
represent closure of the low permeability pathway that was activated
here (Brustovetsky and Dubinsky, 2000). Omission of
Mg2+ from the incubation medium
exacerbated the Ca2+-induced
depolarization and prevented CsA repolarization. The subsequent
addition of 0.5 mM
Mg2+ produced an insignificant
repolarization, but ADP plus oligomycin nevertheless repolarized
mitochondria rapidly.
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Figure 6.
Dependence of the Ca2+-induced
depolarization of isolated, unpurified brain mitochondria on the amount
of added Ca2+ and on the presence of
Mg2+. Initial repeated addition of 0.3 µM TPP+ determined the calibrations
for TPP+ electrode measurements of
. Ca2+ (50 or 100 µM) was added to mitochondria (Mtc) as
indicated by the number near each trace.
Repolarization was induced by 1 µM CsA and 100 µM ADP plus 1 µM oligomycin
(Oligo). In Figures 2-5 and 7, unpurified mitochondria
were respiring on 3 mM succinate.
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Under these experimental conditions the
Ca2+ addition produced only a transient
increase in respiration [Brustovetsky and Dubinsky (2000), their Fig.
4], followed by a slight decrease in steady-state oxygen consumption
for 50 µM Ca2+ and no change
for 100 µM Ca2+ (Table
1). The ability of CsA alone or in
combination with ADP and oligomycin to repolarize mitochondria was not
correlated with consistent changes in respiration. Specifically,
increased respiratory rates were not responsible for repolarizing
.
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Table 1.
Steady-state respiration rates for mitochondria in
mannitol/sucrose medium with 0.5 mM MgCl2 and 3 mM succinate
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In liver mitochondria a number of substances modulate the ability of
CsA to prevent classic mPT induction, including
Mg2+ and FFA (Novgorodov et al., 1994;
Broekemeier and Pfeiffer, 1995). To test whether endogenous FFA could
suppress CsA inhibition of the mPT in brain mitochondria, we
used BSA to bind FFA in Mg2+-free
medium (Bjorntorp et al., 1964). Mg2+ was
removed from the medium because Mg2+ also
can bind FFA (Shinohara et al., 1995). In the presence of BSA the
Ca2+-induced depolarization was weaker
(Fig. 7). In these conditions, despite
the absence of external Mg2+, CsA
repolarized mitochondria. Without BSA the CsA was ineffective. BSA
alone did not repolarize mitochondria significantly. BSA, added after
CsA, induced repolarization. CsA, added after BSA, also increased
. Thus the binding of FFA by BSA facilitated closure
of the low permeability pathway by CsA. However, when 100 µM Ca2+
depolarized mitochondria, CsA failed to repolarize mitochondria despite
the presence of BSA (data not shown). The lack of CsA inhibition after
high Ca2+ challenges might be explained by
an accumulation of endogenous FFA because of the activation of
mitochondrial Ca2+-dependent phospholipase
A2 (PLA2; Waite et al.,
1969; De Winter et al., 1984). Trifluoperazine (100 µM), an inhibitor of mitochondrial PLA2 from liver (Broekemeier et al., 1985), did
not alter CsA efficiency. However, because the ability of
trifluoperazine to inhibit PLA2 in brain
mitochondria is unknown, this result does not rule out modulation of
the low permeability pathway by FFA. Indeed, the addition of 20 µM palmitate exacerbated
Ca2+-induced depolarization and suppressed
CsA repolarization (Fig. 8A). Palmitate itself
induced negligible depolarization. ADP plus oligomycin, added after
CsA, repolarized mitochondria. The addition of 0.05% BSA after CsA
also repolarized mitochondria (data not shown). Thus both exogenous
palmitate and endogenous FFA impeded the closure of the low
permeability pathway by CsA.
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Figure 7.
Restoration of CsA repolarization with the removal
of FFA with 0.05% BSA. Shown are measurements of
with a TPP+ electrode in unpurified mitochondria
respiring on 3 mM succinate in the absence of added
Mg2+. Additions: 50 µM
Ca2+, 1 µM CsA, and 1 µM
FCCP.
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Figure 8.
Palmitic acid and FCCP exacerbated
Ca2+-induced depolarization and prevented the
restoration of by CsA. TPP+
electrode measurements were made in unpurified mitochondria in the
presence of 3 mM succinate and 0.5 mM external
Mg2+. Palmitic acid (10 µM;
Palm; A) or 10 nM FCCP
(B) was added twice before
Ca2+. Other additions: 50 µM
Ca2+, 1 µM CsA, 1 µM
oligomycin, 100 µM ADP, and 1 µM
FCCP.
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CsA failed to close the Ca2+-induced low
permeability pathway in the absence of
Mg2+ or in the presence of FFA (Figs.
6-8). In all of these experiments depolarization was greater than in
the experiments in which CsA successfully repolarized mitochondria.
These results suggest that CsA inhibition may be related to the extent
of depolarization. CsA might not be expected to have any effect if
fell below some threshold. To test this hypothesis,
we pretreated mitochondria with a low concentration of carbonyl cyanide
p-(trifluoromethoxy)phenyl hydrazone (FCCP) that itself did
not cause significant depolarization (Fig. 8B). After
FCCP, 50 µM Ca2+
produced a greater depolarization and CsA did not repolarize mitochondria. Thus the stronger the depolarization, the lower the
probability that CsA would repolarize mitochondria.
To determine the degree of depolarization that was necessary to prevent
CsA-induced closure of the low permeability pathway, we performed a
series of experiments similar to those in Figures 6-8. The degree of
depolarization was varied systematically by applying different
concentrations of Ca2+ or by varying the
concentrations of Mg2+, palmitate, or FCCP
applied before a fixed 50 µM
Ca2+ pulse. The sensitivity of the low
permeability pathway to CsA correlated with the amplitude of
depolarization regardless of the experimental manipulation (Fig.
9). CsA inhibition could not be detected
if mitochondria were depolarized below an amount represented by 0.83 µM TPP+o.
This threshold value should be considered as an estimate and may vary
under different experimental conditions. As an example of this
variation, the threshold for CsA in repolarizing purified brain
mitochondria appears to center between the 1.2 and 1.5 µM level of TPP+ accumulation (Fig.
10). The inability of CsA to repolarize
mitochondria fully in this experiment may be attributable to lingering
deleterious effects of the Percoll purification (Litsky and Pfeiffer,
1997). Thus under all conditions the ability of CsA to repolarize
mitochondria appeared to be correlated inversely with the degree of
mitochondrial depolarization.
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Figure 9.
Determination of threshold for CsA repolarization
in unpurified mitochondria. CsA was unable to repolarize mitochondria
when mitochondria were depolarized beyond the value represented by 0.82 µM external TPP+, independent of the
treatment conditions. Depolarization amplitude was varied by increasing
the added Ca2+ in the presence of 0.5 mM
Mg2+, by decreasing the Mg2+
concentration for a fixed 50 µM Ca2+
challenge, or by pretreating mitochondria with palmitic acid
(Palm) or FCCP for a fixed 50 µM
Ca2+ challenge in the presence of 0.5 mM
Mg2+. [TPP+]o was
measured 1 min after Ca2+ application.
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Figure 10.
Repolarization of purified mitochondria by CsA
correlated with the extent of depolarization induced by different
Ca2+ pulses comparable to that observed for
unpurified mitochondria (see Figs. 2-5). The indicated concentrations
of Ca2+ and 1 µM CsA were added at the
arrows to mitochondria respiring on 3 mM
succinate in the presence of 0.5 mM
Mg2+.
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To determine the ability of CsA to prevent the opening of the low
permeability pathway, we added CsA before mitochondria (Fig. 11). We previously reported that CsA
pretreatment was not sufficient to prevent 100 µM
Ca2+ from activating a sustained
depolarization in CNS mitochondria respiring on 3 mM
succinate (Brustovetsky and Dubinsky, 2000). However, CsA was able to
prevent the sustained depolarization associated with a 50 µM challenge (Fig. 11A). If a small
amount of FCCP was added before Ca2+, the
strength of the depolarization was increased and CsA became ineffective
(Fig. 11B). Thus the ability of CsA to prevent
opening of the low permeability pathway again correlated with a drop of .
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Figure 11.
CsA prevention of activation of the low
permeability pathway was associated with the degree of mitochondrial
depolarization. In the indicated traces 1 µM CsA was
added before unpurified mitochondria in the presence of 3 mM succinate and 0.5 mM
Mg2+. In B, 10 nM FCCP
addition produced only a minor depolarization itself but augmented the
depolarization after 50 µM Ca2+,
nullifying the ability of CsA to prevent a sustained
depolarization.
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CsA effects on the mPT high permeability state
Ca2+-induced changes in light
absorbance of the CNS mitochondrial suspension were monitored to
evaluate the protective action of CsA on the classic high permeability
mPT pore (Fig. 12). Decreased absorbances corresponded to mitochondrial swelling (Dubinsky et al.,
1999), and the amplitude of swelling increased with increasing Ca2+ doses (Kristal and Dubinsky, 1997).
In the presence of 10 mM succinate CsA added before
Ca2+ fully prevented swelling that was
induced by 50 µM Ca2+ even
in the absence of external Mg2+ (Fig.
12A) but failed to protect against 100 µM Ca2+ despite
the presence of Mg2+ (Fig.
12B). In contrast, ADP plus oligomycin suppressed
swelling that was induced by 100 µM
Ca2+ (Fig. 12B).
Moreover, when added after 100 µM
Ca2+, ADP inhibited the process of
swelling (Fig. 12C) whereas CsA did not (Fig.
12B). Thus in vitro CsA exhibited limited
protection against the opening of the high permeability state of the
mPT pore, similar to its limited ability to close the low permeability pathway or to prevent glutamate toxicity.
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Figure 12.
Ca2+-induced swelling of
purified brain mitochondria. Protection by CsA depended on the amount
of added Ca2+. ADP plus oligomycin inhibited the
swelling induced by high Ca2+. Arrows
mark the addition of 50 µM Ca2+
(A), 100 µM Ca2+
(B, C), 1 µM CsA
(B), and 1 µM oligomycin and 100 µM ADP (C). Otherwise, 1 µM CsA and/or 100 µM ADP plus 1 µM oligomycin were present in the medium before the
mitochondrial addition to labeled traces. Oligomycin itself did not
influence mitochondrial swelling. The incubation medium contained 10 mM succinate and, in B and C,
0.5 mM MgCl2. Scale bar in C
applies to the entire figure.
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To investigate the possible causes of CsA failure, we performed
simultaneous measurements of mitochondrial swelling and
. In the presence of 10 mM
succinate 100 µM
Ca2+-induced mitochondrial swelling was
accompanied by a deep, sustained depolarization (Fig.
13A). Neither swelling nor
depolarization was prevented by 1 µM CsA (Fig.
13B). In the presence of 3 mM
succinate plus 3 mM glutamate 100 µM Ca2+-induced
mitochondrial swelling was accompanied by a transient depolarization,
followed by a partial recovery of (Fig.
13C). In this case CsA both improved the recovery of
and completely prevented swelling despite the same
amount of added Ca2+ (Fig.
13D). The presence of glutamate improved mitochondrial
energetics, preventing the oxaloacetate inhibition of succinate
dehydrogenase, and enabled respiration to partially compensate the
Ca2+-induced changes (Brustovetsky and
Dubinsky, 2000). Increasing the Ca2+
concentration in this richer medium produced larger amplitude swelling
and complete sustained depolarization, and CsA again became ineffective
(Fig. 13E,F). Similar results were achieved in
purified mitochondria incubated in media with 125 mM KCl substituted for the sucrose-mannitol (our
unpublished observations). Thus CsA prevention of the mPT opening may
have been limited to conditions in which mitochondria were not
depolarized severely, comparable to the limits on CsA action on the low
permeability pathway.
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Figure 13.
CsA protection against the mPT pore opening
depended on depolarization. Shown are simultaneous measurements of
mitochondrial swelling (A660, top
line) and
([TPP+]o , bottom
line). Mitochondria were incubated in the presence of either 10 mM succinate (A, B) or 3 mM
succinate plus 3 mM glutamate (C-F).
Mitochondria were challenged with either 100 µM
(A-D) or 300 µM
(E, F) Ca2+
pulses. In B, D, and F, 1 µM CsA was added to the medium before
mitochondria. Scale bar in A applies to the entire
figure.
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To test this hypothesis further, we studied the influence of various
mPT modulators on the CsA action. In the presence of succinate plus
glutamate 3.3 µM palmitate caused only a minor depolarization (Fig.
14A).
Ca2+ (100 µM)
added after palmitate induced a completely sustained depolarization
accompanied by large amplitude swelling (compare Fig.
14A with C). In these conditions CsA was
ineffective (Fig. 14B). Similar results were obtained
after pretreatment of mitochondria with 16.7 nM
FCCP (Fig. 14C,D). Omission of
Mg2+ from the incubation medium also
resulted in a Ca2+-induced sustained
depolarization and prevented CsA inhibition of the mPT pore opening
(Fig. 14E,F). In all five cases in the limited substrate environment, after palmitate or FCCP pretreatment, in
the absence of Mg2+, or with excessive
Ca2+a deep sustained depolarization
produced by different mechanisms correlated with the lack of CsA
protection.
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Figure 14.
Treatments potentiating mitochondrial
depolarization prevented CsA inhibition of mPT induction. Shown is the
simultaneous measurement of TPP+ distribution and
light scattering in response to 100 µM
Ca2+ in the presence of 3 mM succinate
plus 3 mM glutamate, conditions in which CsA prevented
mitochondrial swelling and helped to maintain
(see Fig. 8C,D). In A and
B the mitochondria were treated with 3.3 µM palmitate; in C and D
the mitochondria were treated with 16.7 nM FCCP. In
E and F, Mg2+ was
omitted from the medium. In B, D, and
F, 1 µM CsA was added to the medium before
mitochondria. Scale bar in A applies to all parts of the
figure.
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Closure of the high permeability state of the mPT pore by CsA was also
dependent on the potential maintained by mitochondria. PEG addition,
after Ca2+-induced mitochondrial swelling
had reached a steady state, caused mitochondrial shrinkage (Fig.
15A). Under conditions in
which TPP+ electrode measurements
indicated that mitochondria retained some potential, CsA addition
before PEG prevented the shrinkage, indicating that CsA closed the mPT
pore and prevented mannitol-sucrose efflux (Fig. 15B;
Haworth and Hunter, 1979). When a small amount of FCCP was added for
the same Ca2+ challenge or when the
Ca2+ challenge was increased,
mitochondrial depolarization and swelling in response to
Ca2+ were exacerbated, and CsA before PEG
was unable to prevent PEG-induced shrinkage (Fig.
15C-F). Thus CsA prevention of the mPT opening and
closure of the open pore appeared to be associated with mitochondrial polarization, comparable to the limitation observed on effectiveness of
CsA on the low permeability pathway.
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Figure 15.
CsA closed the mPT pore, preventing PEG-induced
shrinkage only when the mitochondria retained some potential. Shown is
the simultaneous measurement of TPP+ distribution
and light scattering in purified mitochondria in response to 100 µM Ca2+ in the presence of 3 mM succinate plus 3 mM glutamate and 0.5 mM Mg2+. A, After
Ca2+-induced mitochondrial swelling had reached a
steady state, polyethylene glycol (PEG, 3350 MW) was
added, promoting osmotic shrinkage in those mitochondria with open mPT
pores. The initial slope of the increase in light scattering after the
PEG addition is proportional to the number of open mPT pores (Haworth
and Hunter, 1979). The instantaneous shift in the absorbance trace was
attributable to dilution of the mitochondrial solution with the PEG
solution. The TPP+ recording was terminated with the
PEG addition because of PEG-induced artifacts. The PEG
addition was performed as described in Figure 5. B,
Addition of 1 µM CsA before PEG prevented mitochondrial
shrinkage (compare the final segment of the absorbance trace with that
of A), indicating that CsA closed the mPT pore.
C, E, An increased
[Ca2+] challenge (E) or
pretreatment with 10 nM FCCP (C)
increased mitochondrial depolarization and swelling in response to
Ca2+. In these conditions 1 µM CsA was
ineffective in closing the mPT (D, F).
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DISCUSSION |
Antagonism of the mPT
In brain mitochondria ADP plus oligomycin was consistently the
most reliable antagonist of Ca2+-activated
mitochondrial permeabilities, comparable to liver (Haworth and Hunter,
1980). Mitochondrial swelling was both prevented and terminated by this
combination. ADP plus oligomycin also inhibited PEG-induced
mitochondrial shrinkage (our unpublished observations), consistent with
their ability both to prevent induction and to promote closure of the
Ca2+-activated low permeability state of
the mPT pore (Brustovetsky and Dubinsky, 2000).
Mechanisms mediating the modulation of CsA-induced inhibition
In contrast to ADP, the ability of CsA to prevent the induction of
and to close the Ca2+-activated high and
low permeability states appeared to correlate with the degree of
steady-state mitochondrial depolarization. Inhibition of the mPT pore
by CsA was modulated by substrate environment, by FFA, by external
Mg2+, by the amount of added
Ca2+, or simply by a minor degree of
uncoupling with FCCP or FFA. Each of these modulators in combination
with elevated Ca2+ could act by different
mechanisms to depolarize mitochondria by themselves, to modulate
Ca2+-induced mPT induction, or to prevent
CsA-induced mPT pore closure directly.
Intramitochondrial Ca2+ accumulation has
been postulated to antagonize the CsA repolarization of liver
mitochondria directly (Crompton and Andreeva, 1994). Thus increasing
the Ca2+ load would result in both greater
depolarization and less CsA inhibition, as observed here. Because of
the sustained depolarization, brain mitochondria failed to accumulate
100 µM Ca2+ rapidly in 3 mM succinate medium (Brustovetsky and Dubinsky, 2000). The
amount of Ca2+ actually accumulated in
these circumstances was comparable to that accumulated after a 50 µM Ca2+ challenge in which
depolarization was not so severe and CsA was able to repolarize
mitochondria (our unpublished results). Thus other factors must be
influencing CsA inhibition in addition to the
Ca2+ load.
Intramitochondrial Ca2+ could activate
mitochondrial PLA2 (De Winter et al., 1984),
leading to excessive accumulation of lysophospholipids and FFA known to
influence the mPT pore complex (Wieckowski and Wojtczak, 1998).
Alternatively, Ca2+ could interact with
acidic phospholipids, e.g., the cardiolipin tightly bound to the
adenine nucleotide transporter (ANT; Beyer and Klingenberg, 1985). From
this position Ca2+ would prevent CsA from
removing ANT-bound cyclophilin, allowing the ANT to maintain the mPT in
an open state (Halestrap and Davidson, 1990).
Mg2+ could potentiate CsA inhibition by
binding to the cytoplasmic face of the inner membrane, inhibiting mPT
induction (Bernardi et al., 1993). Mg2+
suppresses Ca2+-activated mitochondrial
PLA2 (Waite et al., 1969), indirectly preventing
FFA accumulation. Additionally, Mg2+ can
bind FFA directly (Shinohara et al., 1995). Thus the mechanisms of
Ca2+ antagonism and
Mg2+ potentiation of CsA inhibition may be
interrelated, because both influence FFA concentration.
FFA may influence CsA inhibition via modulation of surface potential
(Bernardi et al., 1994). Although the ionized carboxylic groups of FFA
can modulate surface potential (Wojtczak and Schonfeld, 1993), the FCCP
anion has a delocalized charge, is distributed readily within the
mitochondrial membrane, and is unlikely to alter surface potential
(McLaughlin and Dilger, 1980). Thus because low doses of palmitate and
FCCP both acted similarly to prevent CsA inhibition, it is unlikely
that either acted via a mechanism involving surface potential
modulation. In addition, FFA and FCCP can act as uncouplers,
potentially providing an additional pathway for decreasing
mitochondrial potential.
Correlation between CsA inhibition and
mitochondrial polarization
Our data demonstrated that CsA-mediated protection against the
activation and closure of both high and low permeability states of the
mPT was prevented after any manipulation producing excessive mitochondrial depolarizations beyond a threshold value. Operationally, the extent of depolarization consequent to modulation of the mPT by
changing cytosolic Ca2+,
Mg2+, ADP, or fatty acid levels appeared
to determine the probability that CsA will inhibit the depolarization
and/or swelling associated with the mPT effectively. Any treatment
likely to convert the low permeability into the high permeability
pathway also would increase the probability that CsA would become
ineffective by virtue of the associated increases in depolarization.
The existence of any direct voltage dependence to CsA-induced mPT pore
antagonism, although an intriguing possibility, remains to be
determined. may influence both the structure and
function of many mitochondrial membrane proteins. With depolarization
the Ca2+ uniporter loses its ability to
transport Ca2+ even in the presence of a
significant Ca2+ gradient (Kapus et al.,
1991). Also, the sensitivity of the Ca2+
uniporter to ruthenium red decreases 10-fold when mitochondria depolarize (Broekemeier et al., 1994). The high permeability mPT state
may involve the ANT. High enhances ADP binding to the ANT, favoring mPT closure (Halestrap et al., 1997). Although
depolarization did not alter cyclophilin binding to mitochondrial
membranes (Connern and Halestrap, 1996), a possible voltage dependence
of CsA-cyclophilin interactions has not been explored.
Transient opening of the mPT pore may characterize its normal mode of
behavior (Crompton, 1999). Between openings the increased proton
pumping activity of the respiratory chain may compensate for a drop in
. When openings occur at a low frequency, only a
fraction of mitochondria may have open pores at any point in time, and
the apparent in the whole population may be
maintained (Crompton, 1999). Nevertheless, mannitol and sucrose
gradually enter mitochondria with flickering pores, inducing
swelling. This could explain the swelling that is accompanied by
retention of in our experiments with 100 µM Ca2+ (see Figs.
13, 15).
CsA protection against excitotoxicity
The failure of CsA to protect hippocampal neurons over a wide
range of glutamate doses may be explained by the limited conditions under which CsA inhibits Ca2+-activated
permeabilities in isolated mitochondria. Because metabolic impairments,
Ca2+, Mg2+,
and FFA would be expected to act endogenously within neurons, the
inability of CsA to prevent a mPT might reflect varying levels of these
modulations and not the absence of a mPT. At low glutamate concentrations the Ca2+ influx into
neurons might not be sufficient to activate the mPT despite partial
depolarization of mitochondria. Cell death in these circumstances may
be attributable to some other glutamate-initiated process but would not
be CsA sensitive. Midrange glutamate concentrations may increase
[Ca2+]i
sufficiently to induce a CsA-sensitive mPT. Low affinity
Ca2+ dye measurements indicate 300-500
µM NMDA or glutamate increased [Ca2+]i to 12-16
µM (Hyrc et al., 1997; Stout and Reynolds, 1999;
Brustovetsky and Dubinsky, 2000). Because increasing glutamate
concentrations produce increased elevations of
[Ca2+]i (Rajdev
and Reynolds, 1994), cytosolic calcium levels may approach those that
are used to induce the mPT in isolated mitochondria. Actual calcium
concentrations may not be so critical as the portion of the calcium
load sensed by individual mitochondria (Pivovarova et al., 1999). At
the highest glutamate concentrations, massive Ca2+ influx into neurons would be
associated with the greatest mitochondrial depolarizations (Vergun et
al., 1999; Brustovetsky and Dubinsky, 2000). Under these conditions CsA
may be unable either to prevent mPT induction or to close the open mPT.
This may explain the observations that CsA ameliorates mitochondrial
depolarization in only ~30% of cultured neurons (White and Reynolds,
1996; Vergun et al., 1999). In vivo, at risk neurons in an
ischemic penumbral area may be experiencing milder mitochondrial
depolarizations and therefore may be subject to CsA inhibition. Thus
the range of glutamate concentrations and conditions producing
CsA-sensitive toxicity may be narrow, despite mPT activation during
excitotoxic stimulation. Alternatively, multiple neurotoxic pathways
may be activated by glutamate, and antagonizing one with CsA only
permits another to become the principal cause of death. Given the
limited effectiveness of CsA mPT inhibition in brain mitochondria, the
absence of CsA protection may not be conclusive evidence for a lack of
mPT involvement in degenerative processes.
| |
FOOTNOTES |
Received March 13, 2000; revised Aug. 11, 2000; accepted Aug. 24, 2000.
This work was supported by the Huntington's Disease Society of America
and National Institute on Aging Grant AG10034 to J.M.D. and by American
Heart Association Fellowship (Minnesota Affiliate) 9804691X to N.B. We
thank Carter Herman for preparation of the hippocampal cultures and
execution of the toxicity experiments and Dr. Vincent Barnett for the
use of his spectrophotometer. Dr. G. Engel and V. Widmer of Sandoz
Pharmaceuticals kindly provided the CsA.
Correspondence should be addressed to Dr. Janet M. Dubinsky,
Departments of Neuroscience and Physiology, University of Minnesota Medical School, 6-145 Jackson Hall, 321 Church Street SE, Minneapolis, MN 55455. E-mail: dubin001{at}tc.umn.edu.
Dr. Brustovetsky's permanent address: Institute of Theoretical and
Experimental Biophysics, Russian Academy of Science, Pushchino 142292, Moscow Region, Russia.
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TOP
ABSTRACT
INTRODUCTION
