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The Journal of Neuroscience, June 15, 1998, 18(12):4439-4450
Increased Sensitivity to Mitochondrial Toxin-Induced Apoptosis in
Neural Cells Expressing Mutant Presenilin-1 Is Linked to Perturbed
Calcium Homeostasis and Enhanced Oxyradical Production
Jeffrey N.
Keller1, 2,
Qing
Guo2,
F. W.
Holtsberg1,
A. J.
Bruce-Keller2, and
Mark P.
Mattson2
1 Molecular and Cellular Biology Group, Department of
Biology, and 2 Sanders Brown Research Center on Aging and
Department of Anatomy and Neurobiology, University of Kentucky,
Lexington, Kentucky 40536
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ABSTRACT |
Many cases of autosomal dominant early onset Alzheimer's disease
(AD) result from mutations in the gene encoding presenilin-1 (PS-1).
PS-1 is an integral membrane protein expressed ubiquitously in neurons
throughout the brain in which it is located primarily in endoplasmic
reticulum (ER). Although the pathogenic mechanism of PS-1 mutations is
unknown, recent findings suggest that PS mutations render neurons
vulnerable to apoptosis. Because increasing evidence indicates that
mitochondrial alterations contribute to neuronal death in AD, we tested
the hypothesis that PS-1 mutations sensitize neurons to mitochondrial
failure. PC12 cell lines expressing a PS-1 mutation (L286V) exhibited
increased sensitivity to apoptosis induced by 3-nitropropionic acid
(3-NP) and malonate, inhibitors of succinate dehydrogenase, compared
with control cell lines and lines overexpressing wild-type PS-1. The
apoptosis-enhancing action of mutant PS-1 was prevented by antioxidants
(propyl gallate and glutathione), zVAD-fmk, and cyclosporin A,
indicating requirements of reactive oxygen species (ROS), caspases, and
mitochondrial permeability transition in the cell death process. 3-NP
induced a rapid elevation of
[Ca2+]i, which was followed by
caspase activation, accumulation of ROS, and decreases in mitochondrial
reducing potential and transmembrane potential in cells expressing
mutant PS-1. The calcium chelator BAPTA AM and agents that block
calcium release from ER and influx through voltage-dependent channels
prevented mitochondrial ROS accumulation and membrane depolarization
and apoptosis. Our data suggest that by perturbing subcellular calcium
homeostasis presenilin mutations sensitize neurons to
mitochondria-based forms of apoptosis that involve oxidative
stress.
Key words:
Alzheimer's disease; amyloid; caspase; dantrolene; glutathione; malonate; membrane permeability transition; nifedipine; 3-nitropropionic acid; peroxynitrite
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INTRODUCTION |
Alzheimer's disease (AD) is
characterized by amyloid deposition and associated loss of neurons in
brain regions involved in learning and memory processes (for review,
see Yankner, 1996 ; Mattson, 1997a). Mitochondrial dysfunction (Blass,
1993; Kaneko et al., 1995; Benzi and Moretti, 1997; Mattson, 1997b) and
oxidative damage to neuronal membranes, protein, and DNA (Markesbery,
1997) may play prominent roles in the neurodegenerative process in AD. Many cases of early onset autosomal dominant inherited forms of AD are
caused by mutations in the genes encoding presenilin-1 (PS-1) on
chromosome 14 and presenilin-2 (PS-2) on chromosome 1 (for review, see
Hardy, 1997). Presenilins are integral membrane proteins with six to
eight membrane-spanning domains (Doan et al., 1996; Li and Greenwald,
1996; Lehman et al., 1997); they are expressed in neurons throughout
the brain (Cook et al., 1996; Cribbs et al., 1996; Giannakopoulos et
al., 1997), and they are localized mainly in the endoplasmic reticulum
(ER) (Kovacs et al., 1996; Walter et al., 1996; De Strooper et al.,
1997). Recent findings suggest two possible mechanisms whereby
presenilin mutations promote neuronal degeneration in AD. One mechanism
involves altered processing of  -amyloid precursor protein; cultured
cells and transgenic mice expressing PS mutations and fibroblasts from
human carriers of presenilin mutations exhibit increased production of
an amyloidogenic form of amyloid -peptide (A1-42) (Borchelt et
al., 1996; Duff et al., 1996; Scheuner et al., 1996). A second mechanism involves increased sensitivity of neurons to apoptosis; cultured PC12 cells expressing mutant presenilins exhibit increased vulnerability to apoptosis induced by trophic factor withdrawal and
exposure to A (Guo et al., 1996, 1997; Wolozin et al., 1996).
Apoptosis is a complex process involving activation of proteases of the
caspase family, alterations in plasma membrane phospholipids, and
nuclear DNA condensation and fragmentation (Bredesen, 1995; Thompson,
1995). Among the subcellular events that occur during apoptosis,
mitochondrial changes may play a pivotal role in the cell death
decision; a decrease in mitochondrial energy charge and redox state,
loss of transmembrane potential (depolarization), mitochondrial
membrane permeability transition (MPT), and release of substances such
as calcium and cytochrome C that induce apoptosis occur in several
apoptosis paradigms (Kroemer et al., 1997). One approach to studying
the role of mitochondrial impairment in neurodegenerative disorders
involves the use of mitochondrial toxins (Beal, 1996). 3-Nitropropionic
acid (3-NP) is an irreversible inhibitor of complex II (succinate
dehydrogenase) that causes degeneration of striatal and hippocampal
neurons in humans and rats (Ludolph et al., 1992; Beal et al., 1993;
Ming, 1995; Geddes et al., 1996). Cell culture and in vivo
studies indicate that 3-NP can induce neuronal apoptosis (Behrens et
al., 1995; Pang and Geddes, 1997; Sato et al., 1997) by a mechanism
involving oxidative stress (Schulz et al., 1996). We now report that
PC12 cells expressing mutant PS-1 are exquisitely sensitive to
apoptosis induced by 3-NP, which is associated with elevation of
[Ca2+]i and increased oxyradical
production. Agents that suppress elevations of cytoplasmic calcium
levels and antioxidants prevented the adverse effects of mutant PS-1,
suggesting that the apoptosis-enhancing effect of presenilin mutations
involves aberrant calcium regulation and increased oxidative stress.
These findings suggest mechanistic links between presenilin mutations,
perturbed calcium homeostasis, mitochondrial alterations, and neuronal
apoptosis in AD.
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MATERIALS AND METHODS |
Cell lines, experimental treatments, and quantification of
apoptosis. PC12 cell lines (Greene and Tischler, 1976) stably
expressing human wild-type PS-1 and mutant PS-1 (L286V) were
established using methods described in our previous study (Guo et al.,
1996). The untransfected parent cell line, a line transfected with
empty vector, and a line overexpressing wild-type PS-1 were used as controls. Three lines expressing PS-1L286V were used; Western blot
analysis showed that the line overexpressing wild-type PS-1 and each
line expressing PS-1L286V expressed PS-1 protein at a level fivefold to
eightfold over background levels (Guo et al., 1997). Cells were
maintained at 37°C (5% CO2 atmosphere) in RPMI medium
supplemented 10% with heat-inactivated horse serum and 5% with
heat-inactivated fetal bovine serum. Three days before experiments the
cells were incubated in RPMI medium lacking serum and containing 50 ng/ml NGF. 3-NP, glutathione ethyl ester (GSH), propyl gallate,
cyclosporin A, N -nitro-L-arginine, and
7-nitroindazole were purchased from Sigma (St. Louis, MO) and were
prepared as 100-500× stocks in saline solution (0.15 M
NaCl). Nifedipine, dantrolene (Sigma), and BAPTA AM (Molecular Probes,
Eugene, OR) were prepared as 500× stocks in dimethylsulfoxide.
z-VAD-fmk was purchased from Molecular Probes and prepared as a 200×
stock in saline solution.
Methods for quantification of apoptosis are detailed in our previous
studies (Guo et al., 1997; Kruman et al., 1997). Briefly, cells were
stained with the fluorescent DNA-binding dye Hoechst 33342, and the
cellular fluorescence associated with cell nuclei was visualized under
epifluorescence illumination. Cells with condensed and fragmented
nuclei were counted in 40× fields, and the percentage of apoptotic
cells per culture was calculated. Counts were made without knowledge of
cell line or treatment history.
Measurements of ATP levels and succinate dehydrogenase
activity. Cellular ATP levels were quantified using a luciferin
and luciferase-based assay as described previously (Mark et al., 1995). Briefly, after exposure to experimental treatments, cells were rinsed
with PBS and lysed with 0.2 ml of ATP-releasing buffer (Sigma); 10 µl
of the lysate was taken for protein determination. ATP concentrations
in lysates were quantified using a CH II ATP bioluminescence assay kit
(Boehringer Mannheim, Indianapolis, IN) and a luminometer (Optocomp I,
MGM Instruments) according to the manufacturer's protocols. A standard
curve was generated using solutions of known ATP concentrations;
samples were diluted so that readings fell within the linear range. ATP
levels were calculated as nanomoles of ATP per microgram of protein and
normalized to levels in untreated control cultures. Succinate
dehydrogenase activity was measured using the method of Lippold (1982).
Briefly, cells were exposed for 30 min to vehicle or 3-NP in the
presence of 0.1 mM nitro blue tetrazolium. Cells were then
rinsed with medium and scraped in dimethylsulfoxide, and relative
absorbance was measured using a plate reader. Values were expressed as
a percentage of absorbance in parallel vehicle-treated control
cultures.
Assessments of mitochondrial function. Mitochondrial
transmembrane potential was assessed using the dye
5,5',6,6'-tetrachloro-1,1',3,3'-tetraethylbenzimidazolocarbocyanine iodide (JC-1), the uptake of which is directly related to mitochondrial transmembrane potential, using a protocol similar to that reported previously (Moudy et al., 1995; White and Reynolds, 1996). Briefly, cells were incubated for 30 min in the presence of 5 µM
dye, washed twice with Locke's solution (in mM: 154 NaCl,
5.6 KCl, 2.3 CaCl2, 1 MgCl2, 3.6 NaHCO3, 10 glucose, and 5 HEPES buffer, pH 7.2) and then imaged 20-50 min later. Images of JC-1 fluorescence were acquired
using a confocal laser-scanning microscope with excitation at 488 nm
and a 510 nm barrier filter. Levels of JC-1 fluorescence (average pixel
intensity per cell) were quantified using ImageSpace Software
(Molecular Dynamics, Sunnyvale, CA). The conversion of the dye
3-(4,5-dimethylthiazol-2-yl) 2,5-diphenyltetrazolium bromide (MTT) to
formazan crystals was used as a measure of mitochondrial reducing
potential (energy charge and redox state; Musser and Oseroff, 1994;
Shearman et al., 1994). Formazan production was measured 40-60 min
after adding MTT (1 mg/ml) to the incubation medium and after
solubilization of the crystals in dimethylsulfoxide; absorbance (592 nm) was quantified using a plate reader.
Measurements of reactive oxygen species. Levels of cellular
oxidative stress were measured using the fluorescent probes
2,7-dichlorofluorescin diacetate (DCF) and dihydrorhodamine 123 (DHR123) as described previously (Goodman and Mattson, 1994; Mattson et
al., 1997; Kruman et al., 1998). Briefly, cells were incubated for 30 min in the presence of 50 µM DCF or for 30 min in the
presence of 10 µM DHR123, followed by washing in HBSS
containing 10 mM HEPES buffer and 10 mM
glucose. Cells were loaded with the dyes during the last 30 min of
treatment with 3-NP. Cells were imaged using a confocal laser-scanning
microscope (Molecular Dynamics) coupled to an inverted microscope
(Nikon). Cells were located under bright-field optics and then scanned
once with the laser (488 nm excitation and 510 nm emission); cells were
not scanned more than once to avoid artifacts resulting from
light-induced oxidation of the dyes. The laser beam intensity and
photodetector sensitivity were held constant across cultures to allow
quantitative comparisons of relative fluorescence intensity of cells
between treatment groups. Values of cellular fluorescence (average
pixel intensity per cell) were obtained using the software supplied by
the manufacturer (Molecular Dynamics). DCF is trapped mainly in the
cytoplasm and is oxidized by several ROS, most notably hydrogen
peroxide (Page et al., 1993). The dye dihydrorhodamine 123 (DHR) enters
mitochondria and fluoresces when oxidized by ROS, particularly
peroxynitrite, to the positively charged rhodamine 123 derivative (Kooy
et al., 1994; Mattson et al., 1997).
Measurement of intracellular free calcium levels. The
[Ca2+]i in individual PC12 cells was
quantified by fluorescence imaging of the Ca2+
indicator dye fura-2 as described previously (Mattson et al., 1995a;
Guo et al., 1996, 1997). Cultures were incubated for 30-40 min in the
presence of 5 µM fura-2 AM (Molecular Probes), followed by two washes (2 ml/wash) with fresh medium and a 40-60 min incubation before imaging. Immediately before imaging, the normal culture medium
was replaced with HBSS (Life Technologies, Gaithersburg, MD) containing
10 mM HEPES buffer and 10 mM glucose. Cells
were imaged on a Zeiss Axiovert inverted microscope (40× oil immersion objective) coupled to an Attofluor imaging system. The ratio of the
fluorescence emission using two different excitation wavelengths (340 and 380 nm) was used to determine
[Ca2+]i according to the formula:
[Ca2+]i = Kd[(R Rmin)/(Rmax R)](F0/Fs).
The average [Ca2+]i in 10-20 cells
per microscope field was quantified in at least six separate cultures
per treatment condition.
Measurement of caspase activity. Caspase activity was
assessed using the caspase-3 substrate peptide DEVD-biotin using a
method modified from that described previously (Armstrong et al., 1997; Yakovlev et al., 1997) and adapted for in situ analysis.
Briefly, at designated time points after exposure of cultures to 3-NP, cells were exposed for 10 min to Locke's solution containing 0.01% digitonin. Cells were then incubated for 20 min in the presence of 10 µg/ml DEVD-biotin (Calbiochem, La Jolla, CA), washed three times with
PBS (2 ml/wash), and fixed for 30 min in a cold solution of 4%
paraformaldehyde in PBS. Cells were then incubated for 30 min in PBS
containing 5 µg/ml Oregon green streptavidin (Molecular Probes) and
were washed twice with PBS. Images of cellular fluorescence, corresponding to conjugates of activated caspase-3 with DEVD-biotin, were acquired using a confocal laser scanning microscope and levels of
fluorescence (average pixel intensity per cell) were quantified.
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RESULTS |
PC12 Cells expressing mutant PS-1 are hypersensitive to
3-NP-induced apoptosis and exhibit increased oxyradical production
Basal levels of apoptosis under the culture conditions used were
low (2-3%) in each of the PC12 cell lines used in the present study
(Fig. 1A). Exposure of
untransfected and vector-transfected control PC12 cells lines and a
line overexpressing wild-type PS-1 to concentrations of 3-NP from
0.2-10 mM had no significant effect on levels of apoptosis
during a 24 hr exposure period (Fig. 1A). In contrast
to the control cell lines, exposure of PC12 cells expressing the L286V
mutation to increasing concentrations of 3-NP resulted in a
concentration-dependent induction of apoptosis with a significant
increase occurring with 0.2 mM 3-NP (10% apoptosis) and a
maximum of ~25-30% apoptosis in cultures exposed to 20 mM 3-NP; the dose achieving half-maximal effect was ~1
mM (Fig. 1A). Two other clonal lines
expressing PS-1L286V also exhibited a similar increased sensitivity to
3-NP-induced apoptosis (data not shown). A time course analysis of
apoptosis after exposure of each cell line to 2 mM 3-NP
revealed only a small (5-10%) increase in levels of apoptosis in
untransfected cells, vector-transfected cells and cells overexpressing
wild-type PS-1 during a 48 hr exposure period (Fig.
1B). In contrast, levels of apoptosis increased to ~40% during a 48 hr exposure to 3-NP in cells expressing mutant PS-1
(Fig. 1B). To determine whether apoptosis induced by
3-NP in cells expressing mutant PS-1 was specifically related to
inhibition of succinate dehydrogenase, we used malonate, another
inhibitor of succinate dehydrogenase with a structure different from
3-NP. Malonate induced a significant increase in apoptosis in cells expressing mutant PS-1, but not in control cell lines and lines overexpressing wild-type PS-1 (Fig. 1C).
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Figure 1.
PC12 cells expressing mutant PS-1 exhibit
increased sensitivity to apoptosis induced by mitochondrial toxins.
A, Untransfected and vector-transfected control PC12
cells lines and lines overexpressing wild-type PS-1 or mutant (L286V)
PS-1 were exposed for 24 hr to the indicated concentrations of 3-NP and
the percentages of cells with apoptotic nuclei were quantified. Values are the mean and SEM of
determinations made in six to eight cultures. **p < 0.01 compared with each of the other values at that concentration of
3-NP (ANOVA with Scheffe's post hoc test).
B, Untransfected and vector-transfected control PC12
cells lines and lines overexpressing wild-type PS-1 or mutant (L286V)
PS-1 were exposed to 2 mM 3-NP for the indicated time
periods, and the percentages of cells with apoptotic nuclei were
quantified. Values are the mean and SEM of determinations made in at
least six cultures. **p < 0.01 compared with each
of the other values at that time point (ANOVA with Scheffe's
post hoc test). C, Untransfected and
vector-transfected control PC12 cells lines and lines overexpressing
wild-type PS-1 or mutant (L286V) PS-1 were exposed for 24 hr to saline
(Control) or 100 mM malonate and the
percentages of cells with apoptotic nuclei were quantified. Values are
the mean and SEM of determinations made in six cultures.
*p < 0.01 compared with each of the other values
(ANOVA with Scheffe's post hoc test).
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Previous studies provided evidence that the neurotoxicity of 3-NP
(Schulz et al., 1996) and the apoptosis-enhancing action of mutant PS-1
(Guo et al., 1997) are associated with increased generation of
oxyradicals. We therefore used the fluorescent probes DCF and DHR 123 to quantify relative levels of ROS in the different cell lines after
exposure to 3-NP. Exposure of untransfected and vector-transfected
control PC12 cells lines, and a line overexpressing wild-type PS-1, to
2 mM 3-NP resulted in no increase in the levels of DCF
fluorescence (Fig. 2A)
or DHR 123 fluorescence (Fig. 2B) during a 2 hr
exposure period. In contrast, levels of DCF and DHR 123 fluorescence
increased threefold to fourfold during 2 hr exposures to 3-NP in cells
expressing mutant PS-1 (Fig. 2). The increases in levels of DCF and DHR
123 fluorescence in cells expressing mutant PS-1 occurred within 30-60
min of exposure to 3-NP. Similar results were obtained when cells were
loaded with DCF or DHR123 before exposure to 3-NP for 30 and 60 min
(data not shown). These data indicate that one consequence of mutant PS-1 expression is enhanced generation of ROS in response to a mitochondrial toxin.
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Figure 2.
Accumulation of ROS occurs in PC12 cells
expressing mutant PS-1, but not in control cell lines, after exposure
to 3-NP. Untransfected and vector-transfected control PC12 cells lines
and lines overexpressing wild-type PS-1 or mutant
(L286V) PS-1 were exposed to 2 mM
3-NP for the indicated time periods and levels of DCF fluorescence
(A) or DHR 123 fluorescence
(B) were quantified. Values are the mean and SEM
of determinations made in six to eight cultures (20-30 randomly chosen
cells analyzed per culture). *p < 0.05 or
**p < 0.01 compared with each of the other values
at that time point (ANOVA with Scheffe's post hoc
tests).
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Effects of 3-NP on succinate dehydrogenase activity and cellular
ATP levels
One possible explanation for the increased vulnerability of PC12
cells expressing mutant PS-1 to 3NP toxicity is that 3-NP inhibits succinate dehydrogenase to a greater extent in those cells. We therefore assessed succinate dehydrogenase activity 30 min
after exposure to 2 mM 3-NP in untransfected cells, in cells overexpressing wild-type PS-1, and in cells overexpressing mutant
PS-1. 3-NP caused significant decreases in levels of succinate dehydrogenase activity in all three cell lines; the magnitude of the
decrease ranged from 25-40% and was not significantly different among
the cell lines (Fig. 3A). We
next measured ATP levels at 30 and 120 min after exposure of each cell
line to 2 mM 3-NP. Levels of ATP were maintained at
baseline levels during the first 30 min of exposure in all three cell
lines (Fig. 3B). However, at 120 min after exposure to 3-NP,
ATP levels were significantly decreased to 60% of baseline levels in
cells expressing mutant PS-1 but were not decreased in untransfected
cells or cells overexpressing wild-type PS-1 (Fig. 3B).
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Figure 3.
Effects of 3-NP on succinate dehydrogenase
activity and ATP levels in PC12 cells expressing mutant PS-1.
A, Cultures of untransfected PC12 cells and clones
overexpressing either wild-type PS-1 or the L286V PS-1 mutation were
exposed to 2 mM 3-NP for 30 min and levels of succinate
dehydrogenase activity were measured. Values are the mean and SEM of
determinations made in five to seven cultures. *p < 0.02 compared with corresponding value in vehicle-treated cultures.
B, Cultures of untransfected PC12 cells and clones
overexpressing either wild-type PS-1 or the L286V PS-1 mutation were
exposed to 2 mM 3-NP for the indicated time periods and
levels of cellular ATP were quantified. Values are expressed as a
percentage of basal levels and represent the mean and SEM of
determinations made in four to six cultures. Basal ATP levels were:
untransfected cells, 19.4 ± 8 nmol/mg protein; cells
overexpressing wild-type PS-1, 18.3 ± 6 nmol/mg protein; cells
overexpressing mutant PS-1, 19.2 ± 6 nmol/mg protein.
*p < 0.01 compared with values for untransfected
cells and cells overexpressing wild-type PS-1.
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Involvement of elevated
[Ca2+]i, oxyradical production,
and caspase activation in the apoptosis-enhancing action of mutant
PS-1
It was previously reported that PC12 cells expressing mutant PS-1
exhibit enhanced elevation of [Ca2+]i
after exposure to agonists that induce calcium release from IP3-sensitive ER stores (Guo et al., 1996) and after
exposure to a concentration of A that induces apoptosis (Guo et al.,
1997, 1998). We therefore monitored
[Ca2+]i before and after exposure to
3-NP in the different cell lines by fluorescence ratio imaging of the
calcium indicator dye fura-2. The basal
[Ca2+]i was ~80-100 nM
in each cell line examined. After exposure of cells expressing mutant
PS-1 to 2 mM 3-NP, the
[Ca2+]i rose rapidly and
progressively, with levels reaching 180 nM during the
course of a 10 min period (Fig.
4A). In control cell lines and the line overexpressing wild-type PS-1, 3-NP did not induce
an increase of [Ca2+]i during a 10 min
exposure period (Fig. 4A,B).
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Figure 4.
3-NP induces a rapid increase in intracellular
free calcium levels in PC12 cells expressing mutant PS-1, which is
followed by caspase-3 activation. A,
[Ca2+]i was monitored before and after
exposure to 2 mM 3-NP in the indicated cell lines; the
arrow indicates the time point at which 3-NP was added to the culture medium. Values are
the mean of 35-70 cells in three to six separate cultures.
B, [Ca2+]i was measured
5 min after exposure of cells of the indicated lines to 2 mM 3-NP. Values are the mean and SEM of determinations made
in at least six cultures per condition. **p < 0.01 compared with each of the other values (ANOVA with Scheffe's
post hoc tests). C, Cultures of the
indicated lines were exposed for the indicated time periods to 2 mM 3-NP and levels of caspase-3 activity were quantified.
Values are expressed as DEVD fluorescence (average pixel intensity per
cell) and are the mean and SEM of determinations made in four separate
cultures. **p < 0.01 compared with the values for
each of the other three cell lines.
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To determine whether the elevation of
[Ca2+]i and ROS production was
causally linked to apoptosis in cells expressing mutant PS-1, we
examined the effects of agents that suppress elevations of
[Ca2+]i and antioxidants on
3-NP-induced apoptosis. The intracellular calcium chelator BAPTA AM
largely prevented apoptosis induced by 3-NP (Table
1). Similarly, nifedipine (a blocker of
L-type voltage-dependent calcium channels) and dantrolene (a blocker of
calcium release from ER stores) significantly attenuated 3-NP-induced apoptosis. GSH and propyl gallate, two antioxidants previously reported
to protect cultured neurons against apoptosis induced by A (Mark et
al., 1995; Kruman et al., 1997), prevented 3-NP-induced apoptosis in
cells expressing mutant PS-1 (Table 1). Because increased
[Ca2+]i can induce nitric oxide
production and generation of peroxynitrite (Bredt and Snyder, 1992;
Kooy and Royall, 1994), and because peroxynitrite can oxidize DHR 123 (Kooy et al., 1994), we ascertained the effects of inhibitors of nitric
oxide synthase (NOS) on 3-NP-induced apoptosis in cells expressing
mutant PS-1. Levels of apoptosis 24 hr after treatment were untreated
control cultures, 2 ± 1%; 2 mM 3-NP, 14 ± 3%;
100 µM N-nitro-L-arginine plus
2 mM 3-NP, 9 ± 2% (p < 0.05 vs 3-NP alone); and 100 µM 7-nitroindazole plus 2 mM 3-NP, 8 ± 3% (p < 0.05 vs
3-NP alone) (n = 6 separate cultures). In an additional
experiment, levels of DHR fluorescence were quantified (in cells
expressing mutant PS-1) 2 hr after exposure to 2 mM 3-NP
alone or in combination with
N-nitro-L-arginine or 7-nitroindazole. The
NOS inhibitors did not block the 3-NP-induced increase in DHR 123 levels (data not shown). Thus, nitric oxide plays an important role in
3-NP-induced apoptosis, but is clearly not the only contributor to the
increased ROS accumulation induced by 3-NP.
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Table 1.
Evidence for the involvement of calcium influx, ROS
production, mitochondrial membrane permeability transition, and caspase
activation in 3NP-induced apoptosis in PC12 cells expressing mutant
PS-1
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Caspases are believed to play important roles in the effector
phase of apoptosis in many paradigms (Miller, 1997; Yuan, 1997). Measurements of caspase-3 activation after exposure of cells to 3-NP
revealed only a small and transient activation of this caspase at the 1 and 4 hr time points in control PC12 cell lines (untransfected and
vector-transfected) and lines overexpressing wild-type PS-1 (Fig.
4C). In contrast, a marked and sustained activation of
caspase-3 occurred after exposure to 3-NP in PC12 cells expressing
mutant PS-1 (Fig. 4C). The broad-spectrum caspase inhibitor
zVAD-fmk prevented apoptosis induced by 3-NP in cells expressing mutant PS-1 (Table 1), indicating a causal role for caspase activation in the
cell death process.
Evidence for the involvement of decreases in mitochondrial
transmembrane potential and reducing potential and permeability
transition in the apoptosis-enhancing action of mutant PS-1
A decrease in mitochondrial transmembrane potential has been shown
to be associated with the effector phase of apoptosis in many different
systems (Zamzami et al., 1995; Kroemer et al., 1997). We used the dye
JC-1 to examine the effects of 3-NP on relative mitochondrial
transmembrane potential in the different lines of PC12 cells. Levels of
JC-1 fluorescence were essentially unchanged 18 hr after exposure to 2 mM 3-NP in control cell lines and the line overexpressing
wild-type PS-1 (Fig. 5A). In
contrast, the level of JC-1 fluorescence was decreased to <40% of the
control level 18 hr after exposure to 3-NP in cells expressing mutant PS-1 (Fig. 5A). The decrease of JC-1 fluorescence in cells
expressing mutant PS-1 caused by 3-NP was delayed because no decrease
in JC-1 fluorescence occurred during the first 2 hr of exposure (Fig. 5B). Levels of MTT reduction, a measure of mitochondrial
reducing potential, were decreased in a concentration-dependent manner by 3-NP in PC12 cells expressing mutant PS-1 (Fig. 5C). In
contrast, the level of MTT reduction was not significantly changed
after exposure to 3-NP in control PC12 cell lines and in cells
expressing wild-type PS-1 (Fig. 5C; Table
2). Malonate also caused a significant decrease in MTT reduction in cells expressing mutant PS-1 but not in
control cell lines (Fig. 5D).
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Figure 5.
Mitochondrial toxins cause decreases in
mitochondrial transmembrane potential and energy charge in PC12 cells
expressing mutant PS-1, but not in control cell lines. A,
B, Indicated cell lines were exposed for 18 hr
(A) or the indicated time periods
(B) to 2 mM 3-NP, and levels of JC-1
fluorescence were quantified. Values are the mean and SEM of
determinations made in six cultures. **p < 0.01 compared with each of the other values (ANOVA with Scheffe's
post hoc test). C, Indicated cell lines
were exposed to increasing concentrations of 3-NP for 24 hr and levels
of MTT reduction were quantified. Values are the mean and SEM of
determinations made in six cultures. *p < 0.05, **p < 0.01 compared with each of the other values
at the corresponding 3-NP concentration (ANOVA with Scheffe's
post hoc test). D, Indicated cell lines
were exposed to 100 mM malonate for 24 hr and levels of MTT
reduction were quantified. Values are the mean and SEM of
determinations made in six cultures. **p < 0.01 compared with each of the other values (ANOVA with Scheffe's
post hoc test).
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Table 2.
Evidence for the involvement of calcium influx and ROS
production in mitochondrial dysfunction following exposure of PC12
cells expressing mutant PS-1 to 3NP
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Cyclosporin A is an immunosuppressive compound that has been shown to
block the MPT (Marchetti et al., 1996; Zamzami et al., 1996). When PC12
cells expressing mutant PS-1 were cotreated with cyclosporin A and
3-NP, apoptosis and impairment of mitochondrial function were largely
prevented (Tables 1, 2) suggesting links between the MPT, mitochondrial
damage, and nuclear apoptosis. The effect of cyclosporin A was
apparently attributable to specific blockade of the MPT because FK 506, an inhibitor of calcineurin had no effect on 3-NP-induced apoptosis
(data not shown).
Elevations of [Ca2+]i are causally
linked to ROS production and mitochondrial alterations and precede
caspase activation in the apoptotic pathway
To better understand the mechanism whereby mutant PS-1 sensitizes
PC12 cells to apoptosis induced by 3-NP and to reveal the ordering of
events in this apoptotic paradigm, we examined the effects of various
pharmacological agents on ROS production, mitochondrial dysfunction,
and apoptosis induced by 3-NP in cells expressing mutant PS-1. BAPTA
AM, nifedipine, and dantrolene each significantly attenuated the
decrease in MTT reduction otherwise induced by 3-NP (Table 2),
indicating a key role for elevation of intracellular calcium levels in
3-NP-induced mitochondrial dysfunction. The antioxidants GSH and propyl
gallate also prevented the decrease in levels of MTT reduction after
exposure of cells to 3-NP (Table 2), indicating a contribution of
oxyradicals to the mitochondrial dysfunction induced by 3-NP.
Interestingly, levels of MTT reduction were unchanged after 3-NP
exposure in cells incubated in the presence of zVAD-fmk, indicating a
role for caspases in 3-NP-induced mitochondrial impairment.
We next addressed the question of whether elevation of
[Ca2+]i, caspase activation,
and/or MPT contribute to ROS production. Removal of extracellular
calcium, BAPTA AM, nifedipine, and dantrolene each prevented the
increase in DCF fluorescence and DHR 123 fluorescence otherwise induced
by 3-NP (Table 3). As expected, the
antioxidants GSH and propyl gallate also suppressed ROS accumulation.
In contrast, zVAD-fmk was ineffective in preventing the 3-NP-induced
increases of DCF and DHR 123 fluorescence (Table 3), indicating that
caspase activation was not necessary for generation of ROS. zVAD-fmk
also had no effect on the rapid elevation of
[Ca2+]i induced by 3-NP, indicating
that caspases did not play a role in the initial disruption of calcium
homeostasis caused by 3-NP ([Ca2+]i 10 min after exposure to 2 mM 3-NP were control, 75 ± 5 nM; 3-NP, 169 ± 5 nM; zVAD, 83 ± 6 nM; and zVAD plus 3-NP, 162 ± 4 nM (mean + SEM; n = 5-6 cultures). Cyclosporin A attenuated
3-NP-induced increases of DCF and DHR 123 fluorescence (Table 3) but
had no effect on the rapid elevation of
[Ca2+]i induced by 3-NP (data not
shown).
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Table 3.
Pharmacological characterization of the involvement of
calcium, mitochondrial permeability transition, and caspase activation
in 3NP-induced generation of ROS in PC12 cells expressing mutant PS-1
|
|
| |
DISCUSSION |
Expression of a PS-1 mutation in cultured neural cells rendered
the cells vulnerable to apoptosis induced by mitochondrial toxins. The
mechanism underlying the endangering action of mutant PS-1 involves
destabilization of cellular calcium homeostasis and increased ROS
production. Increases of [Ca2+]i and
ROS occurred within several to 30 min of exposure to 3-NP and were
followed several hours later by mitochondrial failure, as indicated by
membrane depolarization and decreased MTT reduction. Untransfected and
vector-transfected control PC12 cell lines and a line overexpressing
wild-type PS-1 were resistant to apoptosis induced by 3-NP and did not
exhibit increased [Ca2+]i and ROS or
mitochondrial membrane depolarization. Pharmacological blockade of
calcium influx and treatment of cells with the calcium chelator BAPTA
AM prevented 3-NP-induced ROS accumulation, decreased mitochondrial
energy charge, and significantly decreased apoptosis in cells
expressing mutant PS-1, indicating that elevation of [Ca2+]i was causally linked to each
subsequent event.
Studies of cultured primary neurons and cell lines showed LD50s for
3-NP and malonate in the ranges of 0.1-5 and 10-100 mM, respectively (Behrens et al., 1995; Zeevalk et al., 1995; Fink et al.,
1996; Pang et al., 1997). These concentrations are similar to those
effective in inducing apoptosis in PC12 cells expressing mutant PS-1 in
the present study. Previous studies of cultured rat hippocampal neurons
(Mattson et al., 1993) and PC12 cells (Luo et al., 1997) showed that
cyanide and other mitochondrial uncouplers can induce increases of
[Ca2+]i that are causally linked to
cell death. Our data suggest that the initial
[Ca2+]i increase after exposure of
cells expressing mutant PS-1 to 3-NP is not the result of mitochondrial
membrane depolarization because JC-1 fluorescence was not decreased
during the first 2 hr of exposure. One possible explanation is that an
early increase in ROS induces calcium release from mitochondria with
preservation of mitochondrial transmembrane potential (Richter, 1997).
Although 3-NP inhibited succinate dehydrogenase to a similar extent in cells expressing mutant PS-1 as compared with control cell lines, ATP
depletion was exacerbated in cells expressing mutant PS-1. Depletion of
ATP levels after exposure of cultured cells to cyanide or 3-NP lagged
behind the elevation of
[Ca2+]i, consistent with
previous studies (Mattson et al., 1993; Erecinska and Nelson, 1994; Luo
et al., 1997; Pang and Geddes, 1997), and therefore is unlikely to play
a major role in the rapid increase of
[Ca2+]i induced by 3-NP. However, ATP
depletion may contribute to delayed calcium release from ER and influx
through plasma membrane voltage-dependent channels as the result of
impaired activity of the ER Ca2+-ATPase, and the
plasma membrane Na+-K+-ATPase
and Ca2+-ATPase. The latter scenario is consistent
with data showing that dantrolene and nifedipine protect PC12 cells
expressing mutant PS-1 against apoptosis induced by 3-NP. Indeed, PC12
cells expressing mutant PS-1 (Guo et al., 1996) and fibroblasts from
human carriers of PS-1 mutations (Ito et al., 1994) exhibit enhanced
calcium release from ER stores in response to a variety of stimuli
including cholinergic agonists and A. Such enhanced
Ca2+ release from ER may be sufficient to render the
cells vulnerable to a level of mitochondrial compromise that would not
kill normal cells.
The oxidation of the probes DCF and DHR 123 in intact cells may result
from the actions of peroxides and peroxynitrite, respectively (Page et
al., 1993; Goodman and Mattson, 1994; Kooy et al., 1994; Mattson et
al., 1997), although these fluorescent probes can also be oxidized by
other ROS. We found that two inhibitors of NOS significantly attenuated
apoptosis induced by 3-NP in cells expressing mutant PS-1, suggesting a
contribution of nitric oxide to the apoptotic process. The finding that
elevation of [Ca2+]i preceded ROS
production after exposure to 3-NP is consistent with roles for nitric
oxide and peroxynitrite in 3-NP-induced apoptosis, because
Ca2+ is a potent activator of NOS (Bredt and Snyder,
1992). Indeed, staurosporine-induced apoptosis in PC12 cells apparently
involves peroxynitrite production secondary to elevation of
[Ca2+]i (Kruman et al., 1998).
Elevations of [Ca2+]i in neurons can
result in generation of ROS, including superoxide anion radical
(Lafon-Cazal et al., 1993), hydrogen peroxide (Mattson et al., 1995b),
and peroxynitrite (Deliconstantinos and Villiotou, 1996). Our data
therefore suggest that PS-1 mutations may promote nitric oxide
production and ROS accumulation in a calcium-dependent manner. The ROS,
in turn, appear to play a central role in subsequent impairment of
mitochondrial function and nuclear apoptosis induced by 3-NP, because
the antioxidants GSH and propyl gallate prevented the decrease in MTT
reduction and nuclear condensation and fragmentation otherwise induced
by 3-NP. Indeed, hydrogen peroxide (Whittemore et al., 1994; Hoyt et
al., 1997) and peroxynitrite (Estevez et al., 1995; Mattson et al.,
1997) were previously shown to impair mitochondrial function and induce
apoptosis in cultured neurons. ROS are implicated in the effector phase
of apoptosis in many different physiological and pathophysiological
settings (Hockenberry et al., 1993; Kane et al., 1993; Kruman et al.,
1997); ROS can disrupt mitochondrial calcium homeostasis and promote
MPT (Richter, 1993; Packer and Murphy, 1995; Brorson et al., 1997).
Cyclosporin A, an inhibitor of MPT (Petronilli et al., 1994), prevented
3-NP-induced apoptosis in PC12 cells expressing mutant PS-1. The
ability of cyclosporin A a to attenuate 3-NP-induced ROS production and
preserve mitochondrial reducing potential in cells expressing mutant
PS-1 suggests that mutant PS-1 perpetuates a vicious cycle in which
perturbed calcium homeostasis promotes MPT and ROS production resulting
in further disruption of calcium homeostasis and nuclear apoptosis
(Fig. 6). Our data are consistent with
previous work showing that cyclosporin A prevents mitochondrial depolarization in cultured cortical neurons exposed to NMDA (Niemenin et al., 1996). The finding that cyclosporin A attenuates accumulation of ROS is at first approximation in contradiction to the data showing
that ROS accumulation occurs before loss of transmembrane potential as
measured by the JC-1 method. One possible explanation of these data is
that there is a time lag between MPT and loss of transmembrane
potential as measured by the JC-1. A second possibility is that
cyclosporin A suppresses ROS production by a mechanism other than
blocking MPT. Inhibition of calcineurin is a well documented action of
cyclosporin A, and recent findings suggest a role for calcineurin in
several different models of apoptosis (Shibasaki and Mckeon, 1995).
However, 3-NP-induced apoptosis in the present study was not blocked by
FK 506, another inhibitor of calcineurin.
View larger version (32K):
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[in a new window]
|
Figure 6.
Working model of the mechanisms whereby PS-1
mutations render neurons vulnerable to mitochondrial dysfunction and
apoptosis. PS-1 is localized in the ER. PS-1 mutations perturb ER
calcium homeostasis in a manner that enhances calcium release when
cells are exposed to various potentially toxic environmental signals
(e.g., glutamate, amyloid -peptide, or agonists that activate the
IP3 pathway). When mitochondrial electron transport is
uncoupled, as in cells exposed to the irreversible succinate
dehydrogenase inhibitor 3-NP, calcium efflux from the mitochondria
occurs followed by ATP depletion. The elevation of
[Ca2+]i in response to mitochondrial
impairment is exacerbated in cells expressing mutant PS-1. High
cytoplasmic calcium levels promote the production of intramitochondrial
and extramitochondrial ROS that damage mitochondrial membranes and
proteins resulting in membrane depolarization ( ¥) and permeability
transition (MPT). These mitochondrial alterations
result in the release of apoptotic factors (AFs) from
mitochondria that then promote nuclear apoptosis. The increased
[Ca2+]i and oxidative stress in cells
expressing mutant PS-1 may also promote aberrant processing of APP
resulting in increased production of amyloidogenic forms of A. A,
in turn, may perpetuate a vicious neurodegenerative cascade by inducing
oxidative stress, disrupting cellular ion homeostasis and further
impairing mitochondrial function. See Discussion for further details
and references supporting different aspects of this model.
|
|
The caspase inhibitor zVAD-fmk prevented loss of mitochondrial
transmembrane potential and energy charge and nuclear apoptosis after
exposure of cells expressing mutant PS-1 to 3-NP. However, the increase
of [Ca2+]i and ROS production induced
by 3-NP was unaffected by zVAD-fmk. These findings suggest that
caspases are involved in 3-NP-induced apoptosis and may act at a point
subsequent to elevation of [Ca2+]i and
ROS production but before mitochondrial failure and nuclear apoptosis.
These findings are consistent with previous studies in other cell types
implicating caspases as upstream effectors of mitochondrial alterations
linked to apoptosis (Harvey et al., 1997; Posmantur et al., 1997). On
the other hand, mitochondrial membrane depolarization and MPT have been
linked to release of molecules that activate caspases and induce
nuclear apoptosis (Anel et al., 1996; Susin et al., 1996; Yang et al.,
1997; Kluck et al., 1997; Shidoji et al., 1997). In neural cells,
CPP32-like caspases may play a prominent role in the late,
postmitochondrial, phase of apoptosis (Kroemer et al., 1997; Yuan,
1997). Because the caspase inhibitor used in the present study
(zVAD-fmk) inhibits a broad range of caspases (including CPP32), the
identity of the caspases that mediate 3-NP-induced apoptosis in cells
expressing mutant PS-1 remains to be established. However, our analysis
of caspase-3 activation does suggest that CPP32 is activated relatively early after exposure to 3-NP, during a time period when ROS
accumulation and disruption of calcium homeostasis occurs.
Interestingly, PS-1 and PS-2 are cleaved by type 3 caspases in cultured
cells undergoing apoptosis; the cleavage site is in the cytosolic loop
domain just adjacent to the normal cleavage site (Kim et al., 1997;
Loetscher et al., 1997). Presenilin mutations result in increased
cleavage by caspase-3, suggesting a role for this cleavage in the
apoptotic process (Kim et al., 1997).
Apoptosis is believed to occur in several prominent neurodegenerative
conditions associated with mitochondrial dysfunction, including AD
(Cotman and Anderson, 1995; Smale et al., 1995), cerebral ischemia
(Linnik et al., 1993; Nitatori et al., 1995; Du et al., 1996), and
Huntington's disease (Portera-Cailliau et al., 1995). The ability of
mutant PS-1 (Guo et al., 1996, 1997; present study) and PS-2 (Wolozin
et al., 1996), and perhaps wild-type PS-2 (Deng et al., 1996; Wolozin
et al., 1996), to enhance apoptosis is consistent with an action of
presenilins at a critical point in the apoptotic pathway. Our findings
suggest that PS-1 mutations affect apoptosis by perturbing ER and
mitochondrial calcium regulation. Recent studies have shown that
mitochondria and ER interact in the regulation of cellular calcium
homeostasis. For example, in lymphocytes, mitochondria control calcium
release from ER stores (Hoth et al., 1997). PC12 cells expressing
mutant PS-1 exhibit altered responses to signals, such as acetylcholine
and bradykinin, that activate receptors linked to inositol phospholipid
hydrolysis and release of calcium from ER stores (Guo et al., 1996). ER
and mitochondrial calcium-regulating systems are increasingly
recognized as playing important roles in fundamental neurophysiological
events, including neurotransmitter release and synaptic plasticity. The present findings therefore suggest that altered subcellular calcium regulation may contribute to neuronal dysfunction before cell death in
AD.
| |
FOOTNOTES |
Received Jan. 5, 1998; revised March 5, 1998; accepted March 27, 1998.
This work was supported by National Institutes of Health Grants
AG14554, NS35253, AG05119, and AG05144 to M.P.M. We thank J. G. Begley, W. Fu, H. Luo, J. Partin, and J. Xie for technical assistance
and J. W. Geddes, Z. Pang, and W. A. Pedersen for helpful discussions.
Correspondence should be addressed to Mark P. Mattson, 211 Sanders
Brown Building, University of Kentucky, Lexington, KY 40536-0230.
| |
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Top
Abstract
Introduction
