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The Journal of Neuroscience, October 15, 1998, 18(20):8145-8152
1-Methyl-4-phenyl-1,2,3,6-tetrahydropyride Neurotoxicity Is
Attenuated in Mice Overexpressing Bcl-2
Lichuan
Yang1, 3,
Russell T.
Matthews1, 3,
Jörg B.
Schulz4,
Thomas
Klockgether4,
Andrew
W.
Liao2,
Jean-Claude
Martinou5,
John B.
Penney Jr.3,
Bradley T.
Hyman2, and
M. Flint
Beal1, 3
1 Neurochemistry Laboratory, 2 Alzheimer's
Disease Research Laboratory, and 3 Neurology Service,
Massachusetts General Hospital and Harvard Medical School, Boston,
Massachusetts 02114, 4 Experimental Neuropharmacology
Laboratory, Department of Neurology, University of Tübingen,
D-72076 Tübingen, Germany, and 5 Glaxo Institute for
Molecular Biology S.A., CH-1228 Plan-les-Ouates, Geneva,
Switzerland
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ABSTRACT |
The proto-oncogene Bcl-2 rescues cells from a wide variety of
insults. Recent evidence suggests that Bcl-2 protects against free
radicals and that it increases mitochondrial calcium-buffering capacity. The neurotoxicity of
1-methyl-4-phenyl-1,2,3,6-tetrahydropyride (MPTP) is thought to involve
both mitochondrial dysfunction and free radical generation. We
therefore investigated MPTP neurotoxicity in both Bcl-2 overexpressing
mice and littermate controls. MPTP-induced depletion of dopamine and
loss of [3H]mazindol binding were
significantly attenuated in Bcl-2 overexpressing mice. Protection was
more profound with an acute dosing regimen than with daily MPTP
administration over 5 d. 1-Methyl-4-phenylpyridinium (MPP+) levels after MPTP administration were similar
in Bcl-2 overexpressing mice and littermates. Bcl-2 blocked
MPP+-induced activation of caspases. MPTP-induced
increases in free 3-nitrotyrosine levels were blocked in Bcl-2
overexpressing mice. These results indicate that Bcl-2 overexpression
protects against MPTP neurotoxicity by mechanisms that may involve both
antioxidant activity and inhibition of apoptotic pathways.
Key words:
MPTP; Parkinson's disease; apoptosis; free radicals; 3-nitrotyrosine; caspases; Bcl-2
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INTRODUCTION |
The neurotoxin
1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) results in a
clinical syndrome closely resembling Parkinson's disease (PD) in both
man and primates (Bloem et al., 1990 ). This meperidine analog
is metabolized to 1-methyl-4-phenylpyridinium (MPP+)
by the enzyme monoamine oxidase B. MPP+ is
subsequently taken up selectively by dopaminergic terminals and
concentrated in neuronal mitochondria in the substantia nigra pars
compacta (SNpc). MPP+ binds to and inhibits
complex I of the electron transport chain (Tipton and Singer, 1993). It
may also cause irreversible inactivation of complex I by generating
free radicals (Cleeter et al., 1992). MPP+ increases
superoxide production in isolated bovine submitochondrial particles
in vitro (Hasegawa et al., 1990) and in vivo
(Sriram et al., 1997). MPTP-induced damage is attenuated in transgenic mice overexpressing superoxide dismutase, implicating free radical generation in its neurotoxicity (Przedborski et al., 1992).
The proto-oncogene Bcl-2 was initially characterized because of its
ability to inhibit apoptosis. Bcl-2 is widely expressed in the nervous
system and is localized to the outer mitochondrial membrane,
endoplasmic reticulum, and nuclear membrane (Krajewski et al., 1993).
Bcl-2 expression inhibits apoptosis in neural cells induced by a
variety of stimuli (Bredesen, 1995). It also inhibits necrotic neural
cell death in some paradigms, such as oxidative neural cell death
induced by depletion of glutathione (Kane et al., 1995). Bcl-2 protects
cells from the lethal effects of H2O2 or
tertbutyl hydroperoxide in a dose-dependent manner (Hockenberry et al.,
1993; Kane et al., 1993). It also protects neural cells from
cyanide-aglycemia-induced lipid peroxidation, compromised mitochondrial respiration, and delayed cell death (Myers et al., 1995),
as well as from AMPA toxicity in cortical cultures (White et
al., 1997). It increases the capacity of neural cell mitochondria to
accumulate calcium (Murphy et al., 1996). A critical role may be in
regulation of membrane potential and volume homeostasis of mitochondria
in response to apoptotic or necrotic stimuli (Vander Heiden et al.,
1997). A recent study showed that Bcl-2 maintains the mitochondrial
membrane potential, enhances H+ efflux after
treatment with either Ca2+ or tertbutyl
hydroperoxide, and prevents activation of the mitochondrial permeability transition (Shimizu et al., 1998).
Because mitochondrial dysfunction and oxidative injury play a role in
the pathogenesis of MPTP neurotoxicity, we investigated whether MPTP
neurotoxicity is attenuated in Bcl-2 overexpressing mice. The mice have
a neuron-specific enolase (NSE) promoter fused to human Bcl-2
cDNA (Martinou et al., 1994). They overexpress Bcl-2 in multiple
tissues, including the SNpc. Previous work showed that they are
resistant to permanent ischemia induced by middle cerebral artery
occlusion (Martinou et al., 1994) and that crossing them into a
transgenic mouse model of amyotrophic lateral sclerosis extends
survival (Kostic et al., 1997).
We examined the effects of both acute and chronic daily dosing regimen
of MPTP in Bcl-2 overexpressing mice compared with littermate controls.
Chronic (daily administration over 5 d) administration of MPTP
induces apoptotic cell death in the SNpc of mice (Tatton and Kish,
1997), whereas no evidence of apoptosis was found with a more acute
dosing regimen (Jackson-Lewis et al., 1995). We suspected that
neuroprotection in Bcl-2 overexpressing mice would be more profound
with a chronic dosing regimen. Surprisingly, there was almost complete
protection against MPTP neurotoxicity induced by an acute dosing
regimen, whereas there was only partial protection with a chronic
dosing regimen. We investigated the mechanism of neuroprotection in
Bcl-2 overexpressing mice by showing that increases in 3-nitrotyrosine,
a marker of oxidative damage, were attenuated and that caspase
activation was inhibited.
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MATERIALS AND METHODS |
Human Bcl-2 overexpressing transgenic animals.
Transgenic mice in which neurons overexpress the human Bcl-2 gene were
generated using the NSE promoter by Martinou et al. (1994). We received male founders (strain NSE73A) and bred them with the same strain female
mice to obtain the hemizygous transgenic offsprings as assessed by
PCR analysis of the DNA extracted from tissue taken from their
tails. These mice are difficult to breed because females have an
imperforate vagina and 50% of males are sterile. Wild-type littermates
were used as controls.
MPTP in PBS was administered using either a chronic dosing
regimen of 20 mg/kg intraperitoneally every 24 hr for five doses or an
acute dosing regimen of 15 mg/kg intraperitoneally every 2 hr for four
doses (n = 10-12 mice in each group). Control
animals in both paradigms were treated with a volume of PBS equal to
the injection volume in the MPTP-treated animals. All animals in both paradigms were killed by decapitation 7 d after the last
injection. For each mouse, one of the two striata was dissected,
immediately frozen on dry ice, and stored at  80°C for
measurement of dopamine and its metabolites. The other hemiforebrain
was frozen in dry ice-cooled isopentane and sectioned on cryostat at 20 µm for dopamine transporter ligand binding. The rest of the brain,
including the mesencephalon, was placed into chilled 4%
paraformaldehyde in PBS, fixed at 4°C for 24 hr, and then
cryoprotected in 20% glycerol at 4°C.
Mice treated acutely with three doses of 15 mg/kg MPTP every 2 hr were
killed at 3 and 6 hr after the last dose (n = 6 per group). The two striata were rapidly dissected and frozen at 80°C for MPP+ measurements. To evaluate the effects of
MPTP on 3-nitrotyrosine levels, mice were injected with either saline
or MPTP at 15 mg/kg intraperitoneally every 2 hr for four doses. Eight
animals in each group were killed at 3 hr after the last dose (the time
point at which we see a maximal increase in 3-nitrotyrosine levels
after MPTP).
Stereological counts of tyrosine hydroxylase neurons. Eight
Bcl-2 and seven littermate control mice were transcardially perfused with 4% buffered paraformaldehyde. Total neuron number in the SNpc was
assessed using stereological principles. The nigra was serially
sectioned, and every sixth section was immunostained with anti-tyrosine
hydroxylase (TH). The number of TH-positive neurons was assessed using
the optical dissector technique and a systemic random sampling scheme
using the stereology subroutines of Bioquant (Nashville, TN)
Image Analysis Software . The volume of the SNpc was calculated by
measuring the area on each section and using the Cavalieri
principle.
Neurochemical analysis. Dissected striatal tissues were
sonicated and centrifuged in chilled 0.1 M perchloric acid
(PCA) (30 µl/mg tissue). The supernatants were evaluated
for levels of dopamine, 3,4-dihydroxyphenylacetic acid (DOPAC),
homovanillic acid (HVA), p-tyrosine, and 3-nitrotyrosine by
HPLC with 16-electrode electrochemical detection as described
previously (Beal et al., 1990). Concentrations of dopamine and
metabolites are expressed as picomoles per milligram of protein.
Free 3-nitrotyrosine data are expressed as ratios of 3-nitrotyrosine
per p-tyrosine to normalize for differing brain concentrations of tyrosine. MPP+ levels (nanograms
per milligram tissue wet weight) were quantified by HPLC with UV
detection at 295 nm. Samples were sonicated in 0.1 M PCA,
and an aliquot of supernatant was injected onto a Brownlee aquapore
X03-224 cation exchange column (Rainin, Ridgefield, NJ). Samples were
eluted isocratically with 90% 0.1 M acetic acid, 75 mM triethylamine-HCL, pH 2.35 adjusted with formic acid,
and 10% acetonitrile. The flow rate was 1 ml/min.
Dopamine transporter binding autoradiography. Twenty
micrometer striatal sections were prewashed 5 min in ice-cold buffer (50 mM Tris-HCl, 5 mM KCl, and 300 mM NaCl, pH 7.9) and then were incubated without drying in
the ice-cold buffer containing 6 nM [3H]mazindol and 300 nM desipramine
for 60 min (nonspecific binding determined in the presence of 10 µM nomifensine) (Javitch et al., 1983). The slices were
washed twice for 3 min in buffer chilled to 4°C and quickly dipped in
cold distilled water. Then, they were hot-air dried and exposed to
Hyperfilm-3H (Amersham, Arlington Heights, IL) at 4°C for
2 weeks. Films were developed with D19 (Eastman Kodak, Rochester, NY)
developer. The films were analyzed with a video-based computerized
image analysis system (MCID; Imaging Research, Inc., St. Catherine's, Ontario, Canada). The total striatal [3H]mazindol
binding (femtomoles per milligram of protein) was calculated using
calibrated plastic 14C standards (Penney et al., 1981; Pan
et al., 1983).
Caspase activation. To examine for caspase activation, we
injected MPP+, the active metabolite of MPTP, into
the anterior striatum of wild-type and Bcl-2 overexpressing mice.
MPP+ (Research Biochemicals, Wayland, MA) was
dissolved in PBS at a concentration of 15 mM, and 0.75 µl
was injected. Four mice were killed at 12 and 24 hr after striatal
MPP+ or saline, respectively. The striata were
dissected from a 2-mm-thick slice and lysed on ice in 50 mM
Tris-HCl, pH 8.0, containing 120 mM NaCl, 0.5% NP-40, 5 mM EDTA, 100 µg/ml PMSF, 2 µg/ml aprotinin, and 10 µg/ml leupeptin, followed by centrifugation at 10,000 × g for 10 min. Samples were diluted to 1 µg/µl protein
and 20 µg/lane subjected to SDS-PAGE on 12% polyacrylamide gels.
After electrophoresis and electroblotting to nitrocellulose membranes,
the blots were blocked in 250 mM Tris-HCl, pH 8.0, 120 mM NaCl, 10% nonfat dry milk, 5% BSA, 1% normal goat
serum, 0.5% Tween 20, and 0.1% azide for 30 min. Next, the blots were
incubated in the first antibody (anti-ICH-1L;
1:1000; Transduction Laboratories, Lexington, KY) at 4°C overnight.
After three washes in PBS (containing 0.05% Tween 20), the membranes
were incubated with secondary alkaline phosphatase-conjugated antibody
for 1 hr, washed three times in PBS, and stained with 0.2 mg/ml
nitroblot tetrazolium chloride and 0.3 mg/ml
5-bromo-4-chloro-3-indolyl-phosphate in 0.1 M Tris-HCl, pH
9.5, containing 50 mM MgCl2 and 100 mM NaCl.
Statistical analysis. Statistical significance of
differences between groups was determined via one-way ANOVA, followed
by Fisher PLSD post hoc test to compare group means. The
correlation of striatal [3H]mazindol binding and
dopamine levels was analyzed by Fisher's R to Z test.
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RESULTS |
Because NSE73A Bcl-2 mice have hypertrophic brains with
increased numbers of neurons in some cell groups, we performed
stereological cell counts of TH-immunopositive neurons in the SNpc of
Bcl-2 overexpressing mice and littermate controls. Although there was a
small increase in TH-immunopositive neurons in Bcl-2 mice compared with
normal controls, the result was not significant. The number of
TH-immunopositive neurons in the SNpc on one side in the controls was
5347 ± 433, and the number was 5125 ± 265 (p = 0.68) in Bcl-2 overexpressing mice.
Similarly, there were no significant differences in striatal dopamine
levels of [3H]mazindol binding at baseline (Figs.
1, 2).
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Figure 1.
Effects of MPTP administered at 15 mg/kg
intraperitoneally every 2 hr for 4 doses on dopamine, DOPAC, and HVA in
wild-type and Bcl-2 overexpressing mice. **p < 0.01; ***p < 0.001 compared with MPTP in
controls.
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Figure 2.
Effects of MPTP administered at 15 mg/kg
intraperitoneally every 2 hr for 4 doses on
[3H]mazindol binding in the striatum in wild-type
and Bcl-2 overexpressing mice. ***p < 0.001 compared with MPTP in controls.
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The effects of MPTP administered acutely at a dose of 15 mg/kg
intraperitoneally every 2 hr for 4 doses on dopamine, DOPAC, and HVA in
wild-type (littermate) and Bcl-2 overexpressing mice are shown in
Figure 1. There was significant, almost complete protection against
depletions of dopamine, DOPAC, and HVA in the Bcl-2
overexpressing mice. Similarly, [3H]mazindol
binding in the striatum also showed almost complete protection (Fig.
2). Representative autoradiograms are shown in Figure
3.
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Figure 3.
Representative autoradiographs of total
[3H]mazindol binding in the striatum in wild-type
and Bcl-2 overexpressing mice after acute administration of MPTP.
Left, Untreated wild-type mouse. Midleft,
MPTP-treated wild-type mouse. Midright, Untreated Bcl-2
transgenic mouse. Right, MPTP-treated Bcl-2 transgenic
mouse.
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The effects of administration of MPTP at a dose of 20 mg/kg daily for 5 consecutive days are shown in Figure 4.
MPTP produced significant depletion of dopamine, DOPAC, and HVA. The
depletions were significantly attenuated in the Bcl-2 overexpressing
mice, but protection was not as complete as that seen with the acute dosing regimen. Similarly, [3H]mazindol binding in
the striatum showed partial significant protection that was not as
profound as that seen with the acute dosing regimen (Fig.
5). Representative autoradiograms are
shown in Figure 6.
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Figure 4.
Effects of MPTP administered at 20 mg/kg
intraperitoneally daily for 5 days on dopamine, DOPAC, and HVA in
wild-type and Bcl-2 overexpressing mice. **p < 0.01 compared with MPTP in controls.
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Figure 5.
Effects of MPTP administered at 20 mg/kg
intraperitoneally daily for 5 days on [3H]mazindol
binding in the striatum in wild-type and Bcl-2 overexpressing mice.
***p < 0.001 compared with MPTP in controls.
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Figure 6.
Representative autoradiographs of total
[3H]mazindol binding in the striatum in wild-type
and Bcl-2 overexpressing mice after chronic administration of MPTP.
Left, Untreated wild-type mouse. Midleft,
MPTP-treated wild-type mouse. Midright, Untreated Bcl-2
transgenic mouse. Right, MPTP-treated Bcl-2 transgenic
mouse.
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MPP+ levels were 3.74 ± 0.63 versus 4.56 ± 1.24 ng/mg wet weight at 3 hr in control and Bcl-2 mice,
respectively (p = 0.55). At 6 hr,
MPP+ levels were 0.97 ± 0.57 and 0.53 ± 0.14 ng/mg wet weight in control and Bcl-2 overexpressing mice,
respectively (p = 0.48). As shown in Figure
7, there was no difference in free
3-nitrotyrosine levels in Bcl-2 overexpressing mice compared with
wild-type mice receiving saline. After administration of MPTP, there
was a significant increase in free 3-nitrotyrosine levels in wild-type
mice, which was significantly attenuated in Bcl-2 overexpressing
mice.
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Figure 7.
Effects of MPTP administration on 3-nitrotyrosine
concentrations in wild-type and Bcl-2 overexpressing mice. MPTP induced
a significant increase in 3-nitrotyrosine at 3 hr after the last dose
compared with saline treated controls, which was significantly
attenuated in Bcl-2 overexpressing mice. *p < 0.05 compared with saline; #p < 0.05 compared with
MPTP-treated wild type.
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By Western blot analysis, anti-ICH-1L (Nedd2/caspase-2)
recognized a major band at ~51 kDa in striatal lysates and,
infrequently, a minor band at 45 kDa (Fig.
8). This apparent molecular weight of 51 kDa is in agreement with that calculated from the predicted sequence of
the Nedd2 protein (Kumar et al., 1994; Harvey et al., 1997).
MPP+ induced an upregulation of this protein at 12 and 24 hr in wild-type animals and to a lesser extent in Bcl-2
overexpressing mice. Further, a cleavage product of ~24 kDa was
detectable by Western blotting in wild-type animals but not in Bcl-2
mice.
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Figure 8.
Striatal MPP+ injections induce
Bcl-2-sensitive activation of caspase-2. MPP+ or
vehicle (saline) were injected into the striatum of wild-type or Bcl-2
transgenic animals, and immunoblot analysis of striatal lysates was
performed at 12 and 24 hr after injection. The 51 kDa band corresponds
to caspase-2 (Nedd2/ICH-1L), and the 24 kDa
band represents a cleaved product of caspase-2.
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DISCUSSION |
Bcl-2 is a protein that inhibits both apoptotic and necrotic cell
death. Although the specific mechanism of action of Bcl-2 is unknown,
it can either detoxify or decrease the production of reactive oxygen
species (Kane et al., 1993; Hockenberry et al., 1993; Lawrence et al.,
1996). There is a direct antioxidant effect of Bcl-2 in PC12 rat
pheochromocytoma cells (Tyurina et al., 1997). Neural cells expressing
Bcl-2 have elevated levels of reduced glutathione/oxidized glutathione
and NADH/NAD+, indicating a shift in cellular
redox potential to a more reduced state (Ellerby et al., 1996). Bcl-2
causes a redistribution of glutathione to the nucleus (Voehringer et
al., 1998). Bcl-2 also has beneficial effects on mitochondrial
function. It enhances the mitochondrial membrane potential and improves
ATP/ADP ratios (Hennet et al., 1993; Smets et al., 1994) and delays ATP
depletion induced by growth factor withdrawal (Garland and Halestrap,
1997). Overexpression of Bcl-2 enhances the mitochondrial calcium
uptake potential of neural cells (Murphy et al., 1996), and it inhibits mitochondrial release of calcium (Baffy et al., 1993). Bcl-2 expression inhibits the mitochondrial transition pore and release of an
apoptogenic protease (Susin et al., 1996; Zamzami et al., 1996; Shimizu
et al., 1998). Bcl-2 expression also blocks the release of cytochrome c
from mitochondria (Kluck et al., 1997; Yang et al., 1997), which is
linked to apoptosis (Liu et al., 1996). The related protein Bcl-xL also blocks cytochrome c release by directly binding
to cytochrome c (Kharbanda et al., 1997) and by blocking rupture of the
outer mitochondrial membrane (Vander Heiden et al., 1997). Bcl-2
targets the protein kinase raf-1 to mitochondria where it helps to
block apoptosis (Wang et al., 1996). In other studies, it blocks the
activation of caspases, indicating that it acts upstream of caspases in
the cell death pathway (Chinnaiyan et al., 1996; Srinivasan et al.,
1996). Bcl-2, as well as the Bcl-2 analog Bcl-xL,
forms ion channels in synthetic lipid membranes (Minn et al., 1997;
Schendel et al., 1997), and it inhibits Bax channel-forming activity
(Antonsson et al., 1997). Bcl-xL inhibits mitochondrial
swelling, regulates membrane potential in response to both necrotic and
apoptotic stimuli (Vander Heiden et al., 1997), and inhibits a loss of
mitochondrial membrane potential by regulating proton flux (Shimizu et
al., 1998).
Substantial evidence implicates mitochondrial dysfunction and free
radical generation in MPTP neurotoxicity. Because Bcl-2 expression can
modify both of these processes, we examined whether MPTP neurotoxicity
is reduced in mice overexpressing Bcl-2. Both necrotic and apoptotic
cell death mechanisms may play a role in MPTP neurotoxicity, depending
on the severity of the insult. In PC12 cells, a high dose of
MPP+ induces rapid necrotic cell death, whereas
lower doses produce delayed apoptotic cell death (Hartley et al.,
1994). MPTP administered at a dose of 20 mg/kg for 5 d induced
apoptotic cell death in the SNpc, as documented using both in
situ end labeling with terminal deoxynucleotidyl transferase and
staining for chromatin condensation with acridine orange (Tatton and
Kish, 1997). In contrast, an acute dosing regimen of MPTP did not show
evidence of apoptotic nuclei (Jackson-Lewis et al., 1995). We therefore
hypothesized that an acute dosing regimen of MPTP would be more likely
to induce necrotic cell death, and a more chronic dosing regimen
administered daily would be more likely to induce apoptotic cell
damage.
In the present experiments, to our surprise, there was almost complete
protection from MPTP-induced decreases in dopamine levels and
[3H]mazindol binding induced by acute
administration of MPTP in mice overexpressing Bcl-2. Although the fall
in [3H]mazindol binding seen after MPTP lesions
could represent downregulation of dopamine transporter numbers or
affinities in surviving dopamine terminals, the fact that MPTP is known
to kill dopamine neurons makes it most likely that this result
represents protection of dopamine neurons and their terminals by Bcl-2.
There was also complete protection against MPTP-induced depletions of
the dopamine metabolites DOPAC and HVA. The neuroprotective effects
were not attributable to an alteration in numbers of substantia nigra
neurons, as shown by stereological cell counts of TH neurons. After
chronic daily administration of MPTP, there was significant partial
protection against depletions of dopamine, HVA, and
[3H]mazindol binding; however, it was much less
marked than the protection seen with the acute dosing regimen. These
results indicate that Bcl-2 protects against both acute and chronic
dosing regimens of MPTP neurotoxicity, but it is much more effective
against an acute dosing regimen in which necrotic cell death would be
expected to predominate. This is of course unexpected, because Bcl-2 is well known to have anti-apoptotic properties. However, if a primary mechanism is to stabilize mitochondria and induce antioxidant effects,
one might well expect protection against both necrotic and apoptotic
cell damage.
The mechanism of neuroprotective effects of Bcl-2 overexpression was
investigated. There were no effects on MPP+ levels
in the Bcl-2 expressing mice compared with littermate controls,
indicating that the neuroprotective effects of Bcl-2 are not mediated
by an alteration in MPTP uptake or metabolism to
MPP+. There also were no significant differences in
[3H]mazindol binding in Bcl-2 expressing mice
compared with littermate controls at baseline, indicating no change in
the dopamine transporter.
Recent evidence indicates that Bcl-2 acts upstream of caspase proteases
in programmed cell death to inhibit their activation. Bcl-2 blocks
release of cytochrome c and subsequent activation of caspases in
vitro (Kluck et al., 1997; Yang et al., 1997). In the cytosol,
cytochrome c binds to apoptotic protease activating factor-1,
the mammalian homolog of CED-4, which may trigger the activation of
caspase-3 (Zou et al., 1997). After MPP+ injections,
our extracts show a major band at 51 kDa, agreeing with the predicted
molecular weight of Nedd2 (Kumar et al., 1994; Harvey et al., 1997).
This probably reflects damage to both dopaminergic terminals and
intrinsic striatal neurons, because MPP+ injections
result in striatal damage (Storey et al., 1994). Striatal MPP+ injections lead to an upregulation of this
protein, which was reduced in Bcl-2 overexpressing mice. Activation of
Nedd2 requires the cleavage of the 51 kDa precursor molecule into
subunits of 19 and 12 kDa (Harvey et al., 1997). Cleavage of Nedd2 has
been reported in other neuronal cell death paradigms, namely in the trophic factor withdrawal-induced apoptosis of differentiated PC12
cells (Troy et al., 1997) and staurosporine-induced apoptosis of
neuronal GT1-7 cells (Srinivasan et al., 1996). At 12 and 24 hr after
injection of MPP+ into the striatum, a cleavage
product of ~24 kDa was detectable in wild-type, but not in Bcl-2
transgenic, animals. At present, we cannot explain the discrepancy
between the predicted molecular weight of the cleavage products (12 and
19 kDa) and the observed 24 kDa band. Because this cleavage product
only occurred after upregulation of Nedd2 protein and the cleavage was
blocked by Bcl-2, we feel that it represents a cleaved subunit of
Nedd2. Possibly, this cleavage product is an intermediate form of the 19 or 12 kDa subunit.
Although neuronal Bcl-2 overexpression did not block upregulation of
Nedd2 protein, the cleavage of Nedd2 into active subunits was
completely blocked, consistent with recent results (Srinivasan et al.,
1996) showing that Bcl-2 blocks apoptosis by preventing processing of
the proforms of caspases into the active forms. These findings
therefore provide in vivo evidence linking
MPP+ to caspase activation and showing that Bcl-2
acts upstream to prevent this activation.
We also examined whether overexpression of Bcl-2 could inhibit
MPTP-induced oxidative damage in vivo. We showed previously that MPTP neurotoxicity is associated with increases in striatal concentrations of free 3-nitrotyrosine, a marker of oxidative damage
mediated by peroxynitrite (Schulz et al., 1995). Furthermore, we and
others found that neuronal nitric oxide synthase inhibitors, which
block the generation of peroxynitrite, produce neuroprotection against
MPTP neurotoxicity in both mice and primates (Schulz et al., 1995;
Hantraye et al., 1996; Przedborski et al., 1996). In the present study,
we found that MPTP-induced increases in free 3-nitrotyrosine were
significantly attenuated in mice overexpressing Bcl-2. These data
therefore provide in vivo evidence that one mechanism of the
neuroprotective effects of Bcl-2 is by inhibiting oxidative damage.
Our results are consistent with recent studies that showed that
expression of Bcl-2 can inhibit lipid peroxidation and
cyanide-aglycemic-induced cell death in vitro (Myers et
al., 1995). Overexpression of Bcl-2 with herpes simplex vectors
enhances neuronal survival in cultured neurons exposed to glutamate and
hypoglycemia and protects against focal ischemia in the striatum
(Lawrence et al., 1996). Our results are also consistent with the
finding that permanent focal ischemic lesions are attenuated in Bcl-2
overexpressing mice and that neurons that survive ischemic lesions
in vivo show upregulation of Bcl-2 (Martinou et al., 1994;
Chen et al., 1995). Overexpression of Bcl-2 also prolongs survival and
attenuates motor neuron degeneration in a transgenic animal model of
amyotrophic lateral sclerosis (Kostic et al., 1997).
The present results suggest that expression of Bcl-2 or administration
of Bcl-2 mimics might be useful in the treatment of PD. Evidence
implicating apoptosis in PD is controversial. Some studies found
evidence for apoptosis based on morphological criteria or in
situ end labeling (Mochizuki et al., 1996; Anglade et al., 1997),
whereas others did not (Kosel et al., 1997). An increase in Bcl-2
protein was found in caudate and putamen of PD patients (Mogi et al.,
1996). Whether neuronal death in PD occurs by either apoptosis or
necrosis, our present results suggest that Bcl-2 may exert
neuroprotective effects. Furthermore, recent evidence indicates that it
can promote regeneration of severed retinal axons in vitro,
independent of its anti-apoptotic effects (Chen et al., 1997). This
suggests that Bcl-2 might exert both neuroprotective effects, as well
as restorative effects, in promoting regrowth of dopaminergic axons in
PD.
Addendum
While this manuscript was in review, others have found that Bcl-2
overexpressing mice are protected against acute MPTP-induced dopamine
depletion (Offen et al., 1998).
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FOOTNOTES |
Received Jan. 5, 1998; revised July 29, 1998; accepted August 3, 1998.
This work was supported by National Institutes of Health Grants
NS10878, NS31579, and AG12992, and Deutsche Forschungsgemeinschaft Grant SFB430 (J.B.S.). We thank Sharon Melanson for her
secretarial assistance.
Correspondence should be addressed to Dr. M. Flint Beal, Neurology
Service/WRN 408, Massachusetts General Hospital, 32 Fruit Street,
Boston, MA 02114.
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Top
Abstract
Introduction
