 |
 Previous Article | Next Article 
The Journal of Neuroscience, April 15, 2001, 21(8):2600-2609
Differential Mechanisms of Neuroprotection by 17  -Estradiol in
Apoptotic versus Necrotic Neurodegeneration
Christoph
Harms1,
Marion
Lautenschlager1, 2,
Alexandra
Bergk2,
Juri
Katchanov2,
Dorette
Freyer2,
Krisztian
Kapinya2,
Ulrike
Herwig1,
Dirk
Megow2,
Ulrich
Dirnagl2,
Joerg
R.
Weber2, and
Heide
Hörtnagl1
1 Institute of Pharmacology and Toxicology and
2 Department of Neurology, Medical Faculty Charité,
Humboldt-University at Berlin, D-10098 Berlin, Germany
 |
ABSTRACT |
The major goal of this study was to compare mechanisms of the
neuroprotective potential of 17  -estradiol in two models for oxidative stress-independent apoptotic neuronal cell death with that in
necrotic neuronal cell death in primary neuronal cultures derived from
rat hippocampus, septum, or cortex. Neuronal apoptosis was induced
either by staurosporine or ethylcholine aziridinium (AF64A), as models
for necrotic cell death glutamate exposure or oxygen-glucose
deprivation (OGD) were applied. Long-term (20 hr) pretreatment (0.1 µM 17 -estradiol) was neuroprotective in apoptotic
neuronal cell death induced by AF64A (40 µM) only in hippocampal and septal neuronal cultures and not in cortical cultures. The neuroprotective effect was blocked by the estrogen antagonists ICI
182,780 and tamoxifen and the phosphatidylinositol 3-kinase (PI3-K)
inhibitor LY294002. In glutamate and OGD-induced neuronal damage,
long-term pretreatment was not effective. In contrast, short-term (1 hr) pretreatment with 17 -estradiol in the dose range of 0.5-1.0
µM significantly reduced the release of lactate dehydrogenase and improved morphology of cortical cultures exposed to
glutamate or OGD but was not effective in the AF64A model. Staurosporine-induced apoptosis was not prevented by either long- or
short-term pretreatment. The strong expression of the estrogen receptor- and the modulation of Bcl proteins by 17 -estradiol in
hippocampal and septal but not in cortical cultures indicates that the
prevention of apoptotic, but not of necrotic, neuronal cell death by 17 -estradiol possibly depends on the induction of Bcl proteins and the
density of estrogen receptor-.
Key words:
apoptosis; necrosis; estradiol; AF64A; staurosporine; oxygen-glucose deprivation; Bcl-2; primary neuronal cultures; estrogen
receptor-; hippocampus; cortex; septum; Alzheimer's disease
| |
INTRODUCTION |
The neuroprotective potential of
estrogens has gained increasing attention during the last years.
Epidemiological evidence suggests that estrogen replacement therapy for
postmenopausal women is associated with an improvement of some measures
of cognitive performance, protection against cognitive deterioration,
and decreased incidence of Alzheimer's disease (Paganini-Hill and
Henderson, 1994 ; Robinson et al., 1994; Sherwin, 1994; Birge,
1996; Tang et al., 1996; Yaffe et al., 1998; Costa et al., 1999).
Moreover, beneficial effects of estrogen on the mortality and morbidity associated with cerebral stroke have been demonstrated (Lafferty and
Fiske, 1994; Grodstein et al., 1996; Hurn and MacRae, 2000). In a
prospective 1 year study, however, estrogen failed to improve cognitive
or functional outcomes of women with mild to moderate Alzheimer's
disease (Mulnard et al., 2000).
The efficacy of estrogen has been shown in several models of
neurodegeneration and ischemic injury in vivo and in
vitro. In ovariectomized rats, physiological concentrations of
estradiol attenuated the extent of brain damage caused by permanent
cerebral ischemia (Dubal et al., 1998). Estradiol also alleviated
stroke injury in reproductively senescent female rats (Alkayed et al., 2000). In primary neuronal cultures, organotypic hippocampal cultures and the hippocampal cell line HT22 estrogens attenuated neuronal injury
caused by hypoxia, excitatory amino acids, superoxide anions, and
hydrogen peroxide (Goodman et al., 1996; Singer et al., 1996; Behl et
al., 1997; Regan and Guo, 1997; Weaver et al., 1997; Sawada et al.,
1998). Moreover, estradiol reduced the neurotoxic effects of
-amyloid as well as the generation of -amyloid in cell cultures (Gridley et al., 1997; Mook-Jung et al., 1997; Keller et al., 1997;
Bonnefont et al., 1998; Xu et al., 1998; Pike, 1999). The overexpression of -amyloid precursor protein mRNA after focal ischemia in female ovariectomized rats was attenuated by a single subcutaneous injection of 17 -estradiol (100 µg/kg) 2 hr before middle cerebral artery occlusion (Shi et al., 1998).
Until now, the efficacy of estradiol has been investigated mainly in
models of neurodegeneration associated with excitotoxicity and
oxidative stress. The aim of the present study was to evaluate the
neuroprotective effect of estradiol in apoptotic neuronal cell death
in vitro and to compare it with that in necrotic neuronal cell death. Apoptotic cell death in primary neuronal cell cultures derived from embryonic cortex, hippocampus, and septum was induced by
ethylcholine aziridinium (AF64A) and staurosporine. AF64A, initially
introduced as a model of cholinergic hypofunction (for review, see
Hanin, 1996) has been shown to initiate neuronal cell death in
vivo and in vitro by activating mechanisms of apoptosis (Rinner et al., 1997; Lautenschlager et al., 2000). The mycotoxin staurosporine activates programmed cell death in virtually all cells
(Falcieri et al., 1993; Raff et al., 1993; Bertrand et al., 1994) and
induces neuronal apoptosis in primary neuronal cultures (Koh et al.,
1995; Wiesner and Dawson, 1996). Both AF64A and staurosporine have been
demonstrated to initiate a caspase-dependent, free radical-independent apoptotic neuronal cell death in primary neuronal cultures (Harms et
al., 2000). Either glutamate exposure or oxygen glucose deprivation (OGD) was used as a model for mainly necrotic types of
neuro-degeneration.
| |
MATERIALS AND METHODS |
Materials. 17 -Estradiol
(cyclodextrin-encapsulated), staurosporine, tamoxifen,
cycloheximide, DMSO, and enzyme standard for the kinetic lactate
dehydrogenase (LDH)-test were obtained from Sigma (Deisenhofen,
Germany); LY 294002 was from Calbiochem (Bad Soden, Germany); ICI
182,780 was from Tocris/Biotrend Chemikalien (Köln, Germany);
neurobasal medium and supplement B27 were from Life Technologies/BRL
(Eggenstein, Germany); modified Eagle`s medium, PBS, HEPES buffer,
trypsin/EDTA, penicillin-streptomycin, L-glutamine, collagen-G, and
poly-L-lysine were from Biochrom (Berlin,
Germany); multiwell plates were from Falcon (Franklin Lakes, NJ); Texas
Red-labeled goat anti-mouse antibody were from Molecular Probes
(Leiden, Holland); the mouse monoclonal antibody to estrogen
receptor- and the polyclonal (rabbit) antibody against estrogen
receptor- were from Alexis (Grünberg, Germany; no. 803-004-C050 and no. 210-135-CO50, respectively); ImmunoFluor mounting
medium was from ICN (Eschwege, Germany); monoclonal antibodies to
Bcl-2, Bcl-xL were from Transduction Laboratories
(Lexington, KY); monoclonal antibodies to Bax were from Santa Cruz
Biotechnology (Heidelberg, Germany) and to -fodrin were from
Biotrend Chemikalien; proteinase inhibitor cocktail and antibodies to
-tubulin were from Boehringer Mannheim (Mannheim, Germany);
secondary anti-mouse horseradish peroxidase-linked antibody was from
Jackson Immunoresearch (West Grove, PA); enhanced chemiluminescence
kits were from Amersham and Pierce (Rockford, IL); x-ray films were
from Kodak (Germany); high-range molecular weight standard was from
Sigma (St. Louis, MO). AF64A was prepared from acetylethylcholine
mustard (Research Biochemicals International, Natick, MA) according to
Fisher et al. (1982).
Primary neuronal cell cultures. Primary neuronal cultures of
hippocampus, septum, and cerebral cortex were obtained from embryos (E)
(E16-E18) of Wistar rats (Bundesinstitut für gesundheitlichen Verbraucherschutz und Veterinärmedizin, Berlin, Germany).
Cultures were prepared according to Brewer (1995) with the following
modifications. Septum, hippocampus, and cerebral cortex were dissected,
incubated for 15 min in trypsin/EDTA (0.05/0.02% w/v in PBS) at
36.5°C, rinsed twice with PBS and once with dissociation medium
(modified Eagle`s medium with 10% fetal calf serum, 10 mM HEPES, 44 mM glucose, 100 U penicillin + streptomycin/ml, 2 mM
L-glutamine, 100 IE insulin/l), dissociated by
Pasteur pipette in dissociation medium, pelleted by centrifugation
(210 × g for 2 min at 21°C), redissociated in starter medium (Neurobasal medium with supplement B27, 100 U penicillin + streptomycin/ml, 0.5 mM
L-glutamine, 25 µM
glutamate), and plated in 24-well plates or 6-well plates in a density
of 200,000 cells per square centimeter. Wells were pretreated by
incubation with poly-L-lysine (0.5% w/v in PBS)
for 1 hr at room temperature, then rinsed with PBS, followed by
incubation with coating medium (dissociation medium with 0.03 w/v
collagen G) for 1 hr at 37°C, then rinsed twice with PBS before cells
were seeded in starter medium. Cultures were kept at 36.5°C and 5%
CO2 and fed beginning from 4 d in
vitro (DIV) with cultivating medium (starter medium without
glutamate) by replacing half of the medium twice a week. The cell
culture media and supplement B27 were free of estrogens.
Injury paradigm. In all models the serum-free primary
neuronal cultures were treated after 10-14 DIV. The condition of cells at various time points after treatment was determined morphologically by phase-contrast microscopy.
AF64A (40 µM) exposure was for 5 hr with subsequent
rinsing and reapplication of conditioned medium. Controls received an equivalent amount of vehicle and were rinsed correspondingly.
Staurosporine was dissolved in DMSO (10 mM stock solution)
and diluted with PBS to give the final concentrations of 100 and 300 nM in culture. The vehicle-treated cultures received the
same amount of DMSO (in PBS) that was present in the highest dose of staurosporine.
For OGD, medium was removed from the cultures and preserved. Cultures
were rinsed twice with PBS, then subjected to OGD for 120 min in a
balanced salt solution at PO2 < 2 mmHg,
followed by replacement of the preserved medium as described previously (Bruer et al., 1997). For standardization of the neuronal damage, the
sister cultures were treated with an excess of glutamate (500 µM; full kill).
Glutamate exposure was performed with 100 µM glutamate
for 30 min with subsequent rinsing and reapplication of conditioned medium.
Treatment with 17 -estradiol, tamoxifen, ICI
182,780, LY 294002, and cycloheximide. Cyclodextrin-encapsulated
17 -estradiol was dissolved in PBS and added to the cell cultures in
a dose range of 30 nM to 10 µM (final concentration in the medium) either 20 hr (long-term pretreatment) or 1 hr (short-term pretreatment) before
the initiation of the injury. In the case of long-term treatment with
glutamate toxicity, cells were washed twice with PBS, and the
conditioned medium without 17 -estradiol was replaced. Tamoxifen was
dissolved in ethanol (10 mM stock solution) and diluted in water (100 µM). The final
concentrations in the medium were 1 µM
tamoxifen and 0.01% ethanol. ICI 182,780 and LY 294002 were dissolved
in DMSO (100 and 65 mM stock solution,
respectively). Cycloheximide dissolved in medium was added to give a
final concentration of 500 ng/ml medium. Tamoxifen, ICI 182,780, LY
294002, or cycloheximide was added at the same time points as estradiol.
Cell death assays. Neuronal injury was quantitatively
assessed by the measurement of LDH in the medium (Koh and Choi, 1987) at 72 hr after AF64A application, at 48 hr after staurosporine application, and at 24 hr after OGD and glutamate exposure.
Western blots. Cells were rinsed with PBS and
harvested in lysis buffer containing (in mM): 150 NaCl, 1 CaCl2, 1 MgCl2, 10 Tris-HCl, pH 7.8, 1% Triton X-100, and proteinase-inhibitor mixture, incubated for 15 min on ice, and centrifuged (12,000 rpm, 4°C). Protein concentration was determined using the BCA protein assay (Pierce), and samples were diluted in SDS sample buffer and boiled for
3 min. Ten micrograms of protein per lane were loaded on 10.0% SDS-polyacrylamide minigels followed by electrophoresis. Blocking was
performed semidry onto polyvinyldifluoride membranes, blocked with 5%
nonfat dry milk, and detected with primary monoclonal antibodies to
Bcl-2 (1:250), Bcl-xL (1:250), Bax (1:250),
-fodrin (1:1000), or -tubulin (1:4000). A secondary anti-mouse
horseradish peroxidase-linked antibody, enhanced chemiluminescence
kits, and x-ray films were used to visualize signals. -Tubulin
served as a positive control for protein loading, and high-range
molecular weight standard was used to determine protein sizes. Cell
lysates served as positive controls for Bcl-2 and
Bcl-xL according to the manufacturer. To provide
semiquantitative analysis of band intensity, band densitometry was
determined from scanned images of nonsaturated immunoblot films, using
Scion Image, version Beta 4.0.2 software (Scion Corporation). To
compare at least three different experiments, for each protein and
brain region the pixel intensity of the bands obtained in each
experiment was added and set as 100%. The individual band was
calculated as percentage of total signals.
Immunocytochemistry. For immunocytochemical analysis, cells
were seeded onto glass coverslips and cultivated for 12 d.
Cultures were then washed with PBS and fixed with freshly prepared 4%
paraformaldehyde in PBS for 15 min at room temperature. Cells then were
washed twice with PBS, permeabilized with 0.3% Triton X-100 in PBS,
and exposed to blocking solution (PBS containing 10% goat serum and 1% BSA) for 30 min at room temperature. Cultures then were incubated with the mouse monoclonal antibody to estrogen receptor- (5 µg/ml) or with the polyclonal (rabbit) antibody against estrogen receptor- (5 µg/ml) for 48 hr at 4°C, washed three times in PBS, and
developed with Texas Red-labeled goat anti-mouse antibody (dilution
1:500) for 30 min at room temperature. After being thoroughly rinsed with PBS, the cultures were placed on a glass slide in ImmunoFluor mounting medium (ICN, Eschwege, Germany) and observed by confocal microscopy. For negative controls, the primary antibody was omitted, resulting in no visible staining.
Confocal laser-scan microscopy and quantitative
immunocytochemical evaluation. Quantitative immunocytochemical
evaluation of cortical, septal, and hippocampal cultures was performed
with an MRC600 confocal imaging system (Bio-Rad, Hemel Hempstead, UK) equipped with a Nikon Optiphot microscope as described previously (Gazzaley et al., 1996). Briefly, an argon-krypton laser was used to
excite Texas Red at 568 nm. The image was visualized using a Leitz
63/1.30 oil immersion objective. All of the confocal parameters were
kept constant throughout the evaluation to yield unbiased comparisons
of different neuronal cultures. The investigator was blinded throughout
the evaluation and did not know from which brain area the culture was
derived. Fifty fields from each culture were randomly selected and
scanned at slow speed. Each digitized image consisted of 768 × 512 pixels. The average pixel intensity of each cell in the field was
selectively determined by a second blinded investigator using the CoMOS
software program (Bio-Rad, Version 7.0a).
Terminal deoxynucleotidyl transferase-mediated biotinylated dUTP
nick end labeling staining. Terminal deoxynucleotidyl
transferase-mediated biotinylated dUTP nick end labeling (TUNEL)
staining was performed with a commercially available ApopTag Kit
(Qbiogene, Heidelberg, Germany) according to the manufacturer's
instructions. TUNEL-positive cells were analyzed for each injury
paradigm in two independent preparations and were counted in a blinded
manner in 20 randomly selected high-power fields. The investigator was
not informed throughout the evaluation from which injury paradigm the
culture was derived.
Data analyses. Data are shown as means ± SEM. To avoid
possible variations of the cell cultures depending on the quality of dissection and seeding procedures, data were pooled from two to three
representative experiments. For statistical analyses the one-way ANOVA
was followed by Tukey's post hoc test.
| |
RESULTS |
17 -Estradiol protects hippocampal but not cortical neuronal
cultures against AF64A-induced neurodegeneration in primary neuronal
cultures
Long-term pretreatment with a single addition of 17 -estradiol
20 hr before AF64A was associated with a marked reduction in LDH
release in hippocampal and septal neurons 72 hr after toxin application
(Fig. 1). The neuroprotective effect of
17 -estradiol in hippocampal and septal neurons was achieved only at
the lower dose range of 0.1 µM and was not apparent at
the higher dose of 1.0 µM. No protection, however, was
observed in cortical neurons. The AF64A-induced increase in LDH release
from cortical neurons (90.4 ± 9.3 U/ml) was not changed after
pretreatment with 0.1 µM (80.8 ± 11.9) or 1.0 µM 17 -estradiol (96.9 ± 8.8). In Figure 2a-c, representative
phase-contrast micrographs of primary neuronal cultures from
hippocampus under control condition and after AF64A exposure without
and with long-term pretreatment with 17 -estradiol are summarized.
AF64A triggered morphological signs of apoptosis including degeneration
of neurites, shrinkage of cell bodies, and fragmentation into condensed
particles, which were at least partly prevented by pretreatment with 17 -estradiol. In contrast, short-term pretreatment of cultured neurons
with various doses of 17 -estradiol 1 hr before AF64A application
did not result in a significant reduction in LDH release within 72 hr
after toxin exposure. The missing protection was obvious in cultures
obtained from cortex, hippocampus, and septum (data not shown).
View larger version (16K):
[in this window]
[in a new window]
|
Figure 1.
Effect of 17 -estradiol on AF64A-induced LDH
release in primary neuronal cultures of hippocampus and septum. At 10 DIV cells were pretreated with 0.1 or 1.0 µM 17 -estradiol for 20 hr before the addition of 40 µM
AF64A or the corresponding vehicle. LDH released into the medium was
measured 72 hr after the addition of AF64A. Data are presented as  increase in LDH release as different from vehicle-treated sister
cultures. The LDH activity in vehicle-treated sister cultures was
38.5 ± 3.7 and 34.1 ± 2.4 U/ml medium in hippocampal and
septal neurons, respectively (n = 5-10
for each condition, pooled from 3 different sets of experiments;
*p < 0.004 vs vehicle-treated cultures;
+p < 0.05 vs AF64A).
|
|
View larger version (179K):
[in this window]
[in a new window]
|
Figure 2.
Phase-contrast microscopy of primary
neuronal cultures after the various injury paradigms with and without
17 -estradiol pretreatment (magnification 250×).
a-c, The effect of long-term
pretreatment with 17 -estradiol on the AF64A-induced
neurodegeneration in hippocampal cultures. The photographs were taken
72 hr after application of AF64A (40 µM).
a, Vehicle-treated control cultures; b,
AF64A-treated cultures; c, AF64A-treated cultures after
pretreatment with 17-estradiol (0.1 µM).
d-i, The effect of short-term
pretreatment with 17 -estradiol on the glutamate- or OGD-induced
neuronal cell death in cortical neurons 24 hr after the injury.
d, Vehicle-treated control cultures; e,
cultures exposed to glutamate (100 µM); f,
cultures exposed to glutamate 1 hr after pretreatment with 17 -estradiol (10.0 µM); g, cultures
exposed to OGD (2 hr); h, cultures exposed to
OGD 1 hr after pretreatment with 17 -estradiol (0.1 µM); i, cultures exposed to OGD 1 hr
after pretreatment with 17 -estradiol (0.5 µM).
|
|
17 -Estradiol does not prevent
staurosporine-induced neurodegeneration
In staurosporine-induced apoptotic neuronal cell death, neither
short-term (1 hr) nor long-term (20 hr) pretreatment with 0.1 or 1.0 µM 17 -estradiol was effective in reducing the release of LDH. In the hippocampus the application of staurosporine (300 nM) induced an increase in LDH release from 77.2 ± 5 to 128.6 ± 8.2 U/ml 48 hr after addition (n = 6-12; p < 0.05). This increase was not significantly
changed after short-term or long-term pretreatment with both doses of
17 -estradiol (e.g., 138.7 ± 3.0 and 136.2 ± 11.8 after
pretreatment with 0.1 µM 17 -estradiol, 1 and 20 hr before, respectively; n = 6). Similarly in
cortical cultures LDH release increased from 66 ± 6.8 to
119.2 ± 5.1 U/ml 48 hr after addition of staurosporine (300 nM; n = 6-12; p < 0.05) with no significant change of the increase after pretreatment
with 17 -estradiol (e.g., 121.9 ± 7.3 and 130.6 ± 9.6 U/ml after pretreatment with 0.1 µM 17 -estradiol, 1 and 20 hr before, respectively; n = 6).
Only short-term pretreatment with 17 -estradiol reduces LDH
release from primary cortical cultures after glutamate exposure
Exposure of cortical neurons to 100 µM glutamate for
30 min induced marked neuronal cell death associated with a
considerable increase in LDH release within 24 hr. Pretreatment of the
cortical cultures with various doses of 17 -estradiol 1 hr before
glutamate attenuated the increase in LDH release. The neuroprotection
was significant at 0.1 and 1.0 µM but started to
disappear at higher doses (Fig.
3A; Table
1). In phase-contrast microscopy, the
protective effect of 17 -estradiol was clearly visible (Fig.
2e,f). No neuroprotection was achieved
after long-term pretreatment of the cultures with various doses of 17 -estradiol (20 hr before 100 µM glutamate), whereas in glutamate-treated sister cultures short-term pretreatment with 17 -estradiol significantly reduced LDH release (Table 1).
View larger version (24K):
[in this window]
[in a new window]
|
Figure 3.
A, Effect of 17 -estradiol on
glutamate-induced LDH release in primary neuronal cultures of cortex.
At 10 DIV, cells were pretreated with 0.1, 1.0, or 10.0 µM 17 -estradiol for 1 hr before the addition of 100 µM glutamate or the corresponding vehicle. LDH released
into the medium was measured after 24 hr. Data are presented as increase in LDH release as different from vehicle-treated sister
cultures (n = 6-8 for each condition, pooled from
2 different sets of experiments; *p < 0.001 vs
vehicle-treated cultures; +p < 0.005 vs glutamate). B, Effect of 17 -estradiol on LDH
release after OGD in primary neuronal cultures of cortex. At 10 DIV,
cells were pretreated with 0.1, 0.5, 1.0, or 5.0 µM 17 -estradiol for 1 hr before OGD. LDH released into the medium was
measured 24 hr after OGD. Data are presented as increase in LDH
release as different from vehicle-treated sister cultures. The
LDH activity in vehicle-treated sister cultures was 63.8 ± 1.2 (n = 9-24 for each condition, pooled from 2 different sets of experiments; *p < 0.001 vs
vehicle-treated cultures; +p < 0.05 vs
OGD + vehicle).
|
|
View this table:
[in this window]
[in a new window]
|
Table 1.
Effect of short-term (1 hr) and long-term (20 hr)
pretreatment with 17 -estradiol on the increase in LDH release ( U/ml medium) in cortical and hippocampal primary neuronal cultures 24 hr after exposure to glutamate (100 µM)
|
|
Only short-term pretreatment with 17 -estradiol protects
against neurodegeneration in cortical cultures induced by
oxygen-glucose deprivation
Comparable to its neuroprotective efficacy in glutamate-induced
neuronal cell death, 17 -estradiol was effective in OGD-related neuronal cell loss only after short-term pretreatment (1 hr). The
effect was maximal in the dose range of 0.5-1.0 µM (Fig.
3B). In the presence of 0.5 µM 17 -estradiol, neurons appeared to be resistant against the influence
of OGD (Fig. 2g-i). At the dose of 0.1 µM, which was effective as long-term
pretreatment in the apoptotic model of neurodegeneration, 17 -estradiol did not attenuate the release of LDH. No protection was
achieved after long-term pretreatment with 17 -estradiol (20 hr). In
this experiment, the OGD-induced increase in LDH release from cortical
neurons (59.7 ± 7.0 U/ml) was not changed after pretreatment with
0.1 µM (56.1 ± 3.7), 0.5 µM (64.5 ± 7.5), or 1.0 µM 17 -estradiol (60.5 ± 4.8).
Modulation of Bcl-2 expression by 17 -estradiol in
primary neuronal cultures
In hippocampal cultures, 17 -estradiol (30 and 100 nM) increased the levels of Bcl-2 24 and 48 hr after
application (Fig. 4A).
Increased Bcl-2 levels persisted up to 68 hr after the addition of 17 -estradiol (Fig. 5A). At
this late time point increased Bcl-xL levels were
found. In contrast, we did not observe a change of the expression of
Bcl-2 and Bcl-xL in cortical cultures after 17 -estradiol treatment.
View larger version (29K):
[in this window]
[in a new window]
|
Figure 4.
A, Effect of 17 -estradiol (0.03 and 0.10 µM) on the expression of Bcl-2 in hippocampal
and cortical neuronal cultures. Neuronal cultures derived from
hippocampus or cortex were maintained for at least 10 DIV before a
24-48 hr exposure to 17 -estradiol (30 or 100 nM) and
then processed for Western blots. 1, Vehicle-treated
cultures; 2, 24 hr exposure to 0.10 µM 17 -estradiol; 3, 48 hr exposure to 0.10 µM 17 -estradiol; 4, 48 hr exposure to
0.03 µM 17 -estradiol. B, Antagonism of
17 -estradiol-induced increase in Bcl-2 and Bcl-xL in
hippocampal cultures by cycloheximide and tamoxifen. At 10 DIV,
hippocampal cultures were treated for 48 hr and then processed for
Western blots. a, Vehicle-treated cultures;
b, cycloheximide (500 ng/ml medium)-treated cultures;
c, tamoxifen (1 µM)-treated cultures;
d, 17 -estradiol (0.1 µM)/cycloheximide
(500 ng/ml medium)-treated cultures; e, 17 -estradiol
(0.1 µM)/tamoxifen (1 µM)-treated cultures;
f, 17 -estradiol (0.1 µM)-treated
cultures; g, 17 -estradiol (1.0 µM)-treated cultures.
|
|
View larger version (35K):
[in this window]
[in a new window]
|
Figure 5.
A, Effect of 17 -estradiol (0.1 µM) and AF64A (40 µM) on the expression of
Bcl-2, Bcl-xL, Bax, and -tubulin in hippocampal
and cortical neuronal cultures. Neuronal cultures derived from
hippocampus or cortex were maintained for at least 10 DIV before the
experiment. Cells were treated with vehicle or 17-estradiol and 20 hr later with vehicle or AF64A. Cells were processed for Western blot
48 hr after application of AF64A. At least three separate experiments
were performed. 1, Vehicle/vehicle-treated cultures;
2, 17-estradiol/vehicle-treated cultures;
3, vehicle/AF64A-treated cultures; 4,
17-estradiol/AF64A-treated cultures. The semiquantitative analysis
of the Western blots of Bcl-2 and Bcl-xL by band
densitometry from three separate experiments is shown.
B, Effect of 17 -estradiol (0.1 µM) and
staurosporine (300 nM) on the expression of Bcl-2 in
hippocampal and cortical neuronal cultures. Neuronal cultures derived
from hippocampus or cortex were maintained for at least 10 DIV before
the experiment. Cells were treated with vehicle or 17-estradiol and
20 hr later with vehicle or staurosporine. Cells were processed for
Western blot 24 hr after application of staurosporine.
1, Vehicle/vehicle-treated cultures; 2,
17-estradiol/vehicle-treated cultures; 3,
vehicle/staurosporine-treated cultures; 4,
17-estradiol/staurosporine-treated cultures. The semiquantitative
analysis of the Western blots by band densitometry is shown from four
separate experiments.
|
|
An increase in Bcl-2 expression also occurred 48 hr after the
application of AF64A (40 µM) in the hippocampal cultures.
The pretreatment with 17 -estradiol resulted in a further
synergistic increase in Bcl-2 levels (Fig. 5A). Levels of
Bcl-xL and Bax were not altered 48 hr after AF64A
treatment. Staurosporine rather suppressed the 17 -estradiol-induced
increase in Bcl-2 in the hippocampal neurons (Fig. 5B).
Antagonism of long-term neuroprotective effect of estradiol by
tamoxifen, ICI 182,780, and cycloheximide
To show that the long-term effect of estradiol is based on a
receptor-mediated, transcription-regulating mechanism, we additionally treated hippocampal cultures with tamoxifen, ICI 182,780, or
cycloheximide. The neuroprotective effect of 17 -estradiol on
AF64A-induced apoptotic cell death was abolished by receptor blockade
as well as by inhibition of protein synthesis. The results on LDH
release are summarized in Table 2. In
addition, both tamoxifen and cycloheximide reduced the increase in the
expression of Bcl-2 and Bcl-xL observed 48 hr
after treatment with 17 -estradiol (Fig. 4B).
Tamoxifen, however, which has a comparable relative affinity for
estrogen receptor- versus estrogen receptor- [7 and 6, respectively; see Kuiper et al. (1997)], did not antagonize the
neuroprotection by short-term treatment with 17 -estradiol against
glutamate exposure (Table 1).
View this table:
[in this window]
[in a new window]
|
Table 2.
Loss of the neuroprotective effect of 17- estradiol on
AF64A (40 µM)-induced neuronal cell death in hippocampal
and septal cell cultures after pretreatment with tamoxifen, ICI
182,780, LY 294002, or cycloheximide
|
|
Lower expression of estrogen receptor- in cortical neurons
To find out whether the neuroprotectivity of 17 -estradiol
against AF64A-induced apoptosis and the increase in Bcl expression depends on the presence of estrogen receptor-, we compared the expression of both estrogen receptor- and estrogen receptor- in
the septal, hippocampal, and cortical neuronal cultures by immunocytochemical methods. The immunostaining for estrogen
receptor- was considerably weaker in the cortical neurons than in
hippocampal and septal neurons (Fig.
6A). The intensity of
immunoreactivity was quantified by means of confocal microscopy in 139 neurons of each culture system in a randomized, blinded manner. The
mean pixel intensity was significantly higher in septal neurons
(13.06 ± 0.57) and hippocampal neurons (11.37 ± 0.57) as
compared with cortical neurons (7.62 ± 0.47; p < 0.05, one-way ANOVA on ranks followed by Tukey's post hoc
test). In addition, the immunoreactive neurons were differentiated
according to fluorescence intensity. The median pixel intensity of all
counted cells (8.9) was taken as a border between cells with low or
high intensity. In cortical cultures, neurons with low fluorescence
intensity prevailed (100 of 139 neurons). The opposite distribution was
found in septal and hippocampal cultures (Fig. 6C). In
contrast, the immunostaining for estrogen receptor- was more intense
in the cortical neurons than in hippocampal and septal neurons (Fig.
6B). The intensity of immunoreactivity was quantified
by means of confocal microscopy in 140 neurons of each culture system
in a randomized, blinded manner. The mean pixel intensity was
significantly lower in septal neurons (7.85 ± 0.31) and
hippocampal neurons (8.61 ± 0.44) as compared with cortical
neurons (10.86 ± 0.39; p < 0.05, one-way ANOVA
on ranks followed by Tukey's post hoc test). Again,
the immunoreactive neurons were differentiated according to
fluorescence intensity. The median pixel intensity of all counted cells
(8.3) was taken as a border between cells with low or high intensity. In cortical cultures, neurons with high fluorescence intensity prevailed (91 of 140 neurons). The opposite distribution was found in
septal and hippocampal cultures (Fig. 6C).
View larger version (71K):
[in this window]
[in a new window]
|
Figure 6.
A, Immunocytochemical analysis on the localization
of estrogen receptor- (A) and estrogen
receptor- (B) in cortical, hippocampal, and
septal neurons. Cells derived from cortex, hippocampus, or septum were
cultivated for 12 d before they were fixed in 4% formaldehyde for
15 min at room temperature. After permeabilization with 0.3% Triton
X-100 and exposure to blocking solution, cultures were incubated with
the mouse monoclonal antibody to estrogen receptor- or the
polyclonal (rabbit) antibody against estrogen receptor- for 48 hr at + 4°C and developed with Texas Red-labeled goat anti-mouse antibody
(1:500) for 30 min at room temperature. Cultures were placed on a glass
slide in ImmunoFluor mounting medium and observed by confocal
microscopy (magnification 630×). C, Distribution of
estrogen receptor-- and estrogen receptor--immunoreactive neurons
according to immunofluorescence intensity in cortical, hippocampal, and
septal neuronal cultures. The quantitative immunocytochemical analysis
was performed by means of confocal microscopy. The average pixel
intensity was determined in 139 and 140 neurons, respectively, of each
of the culture systems selected in a randomized, blinded manner. The
median pixel intensity of all counted cells (8.9 and 8.3, respectively)
was taken as a border between cells with low or high intensity.
|
|
Involvement of PI3-K cascade in the neuroprotectivity of
17 -estradiol
As a further proof for the involvement of estrogen receptor-,
we tested the influence of the inhibitor of PI3-K, LY294002, on the
neuroprotectivity of 17 -estradiol in the AF64A model. Activation of
PI3-K is an important step in the insulin-like growth factor 1 (IGF-1)
receptor pathway. It has been demonstrated recently that 17 -estradiol induces an activation of this pathway only by stimulation
of the estrogen receptor- and not of the estrogen receptor-
(Kahlert et al., 2000), When LY294002 was added (5 µM)
concomitantly with 17 -estradiol, the protective effect of 17 -estradiol was abolished completely (Table 2).
Assessment of apoptosis versus necrosis
To clearly differentiate between the mode of neuronal cell death
in the various types of injury, we used two different approaches in
addition to previously published distinctions. First, we compared the
number of TUNEL-positive cells in cortical cultures per high power
field (n = 20) in the various conditions. The following numbers of TUNEL-positive cells were found: in control cultures, 6 ± 2; 24 hr after glutamate exposure, 7.5 ± 3; 24 hr after OGD, 3 ± 2; 24 hr after staurosporine, 34 ± 6; and 48 hr after
addition of AF64A, 26 ± 4. As a second approach the breakdown
pattern of -fodrin was analyzed to distinguish between necrosis and
apoptosis. According to Nath et al. (1996), -fodrin is degraded to a
120 kDa fragment in apoptotic neurons but not in necrotic neurons (for
review, see Wang, 2000). A considerable increase in the 120 kDa
fragment of -fodrin was only found in staurosporine-treated cells
and time dependently after AF64A treatment but not after exposure to
glutamate or OGD (Fig. 7). The results of
both techniques clearly indicate that in the case of AF64A and
staurosporine the apoptotic cell death predominates, whereas in the
case of glutamate and OGD cell death is necrotic in nature.
View larger version (41K):
[in this window]
[in a new window]
|
Figure 7.
-Fodrin breakdown pattern as marker for caspase
and calpain activation in the various models of neuronal death.
Neuronal cultures derived from cortex were maintained for at least 10 DIV before the experiment. Cells were harvested for Western blot
analysis as follows: 1, control-treated cultures;
2, glutamate (100 µM)-treated cultures (24 hr after exposure); 3, cultures 24 hr after OGD;
4, staurosporine (300 nM)-treated cultures
(24 hr after application); 5, staurosporine (300 nM)-treated cultures (48 hr after application);
6, AF64A (40 µM)-treated cultures (24 hr
after application); 7, AF64A (40 µM)-treated cultures (48 hr after application);
8, AF64A (40 µM)-treated cultures (72 hr
after application). The semiquantitative analysis of the Western blots
of the 120 kDa fragment of -fodrin (p120) by
band densitometry from three separate experiments is shown.
|
|
| |
DISCUSSION |
The present data provide in vitro evidence that
different mechanisms are involved in the neuroprotective efficacy of
estrogens depending on whether the injury model used is related to the
apoptotic or necrotic type of neuronal cell death. Moreover, brain
region-specific differences in neuroprotection by 17 -estradiol were
observed. In neuronal apoptotic cell death as induced by AF64A,
neuroprotection was only achieved by long-term pretreatment with 17 -estradiol in the 0.1 µM dose range in
hippocampal and septal but not cortical primary cultures. The
neuroprotection was reversed both by the estrogen receptor antagonists
ICI 182,780 and tamoxifen and by inhibition of protein synthesis. These
findings indicate that prevention of apoptotic neuronal cell death is
probably associated with transcriptional regulation, mediated by
activation of estrogen receptors. Similar evidence has been obtained
for the estrogen neuroprotection against -amyloid in cultured
hippocampal neurons (Pike, 1999). Short-term mechanisms unrelated to
estrogen receptors were not protective in the AF64A model for apoptotic neurodegeneration.
When apoptotic cell death was induced by the broad spectrum protein
kinase inhibitor staurosporine, hippocampal, septal, and cortical
neurons were not protected after either long-term or short-term
pretreatment with 17 -estradiol. The failure of 17 -estradiol to
protect against staurosporine-induced apoptosis is explained at least
partly by the following findings. First, it has been demonstrated in
the present study that staurosporine prevents the 17 -estradiol-induced expression of Bcl-2. Second, the inhibition of
protein kinases by staurosporine could further contribute to the
inefficacy of 17 -estradiol. Estrogen neuroprotection in primary
cortical neurons after glutamate excitotoxicity is mediated by
activation of the mitogen-activated protein kinase signaling pathway
(Singer et al., 1999).
In neuronal injury caused by excitotoxicity or hypoxia, only short-term
pretreatment and the use of higher doses of 17 -estradiol (0.5-1.0
µM) provided neuroprotection that was not prevented by estrogen receptor blockade. This is in agreement with previous results
demonstrated in cortical, hippocampal, and mesencephalic dopaminergic
cultures (Goodman et al., 1996; Behl et al., 1997; Regan and
Guo, 1997; Sawada et al., 1998). The independence of the
neuroprotective effect of estrogen in excitotoxicity and hypoxia from
estrogen receptor-mediated pathways or protein synthesis has been
demonstrated by several groups (Sawada et al., 1998; Moosmann and Behl,
1999; Zaulyanov et al., 1999). These findings and the immediate
efficacy of higher doses of 17 -estradiol indicate that mechanisms
unrelated to transcriptional regulation are involved, such as
antioxidant properties of estrogens, direct inhibition of NMDA
receptors (Weaver et al., 1997), rapid release of calcium from
intracellular stores (Beyer and Raab, 1998), stimulation of guanylate
cyclase activity (Chen et al., 1998), blockade of calcium entry via
L-type calcium channels (Mermelstein et al., 1996), and stabilization
of mitochondrial function (Mattson et al., 1997). In addition, the
involvement of a possible membrane-binding site on neurons for various
steroids including estrogens is discussed (for review, see Behl and
Holsboer, 1999). Our finding of the inefficiency of 17 -estradiol
(0.1-5.0 µM) after long-term pretreatment in glutamate
and OGD-induced cell death is in contrast to the significant degree of
protection against excitotoxicity observed in primary cortical neurons
or hippocampal slice cultures, when low doses of 17 -estradiol
(1-50 nM) were added 24 hr before the excitotoxin (Singer
et al., 1996; Bi et al., 2000). In the hippocampal slice cultures,
however, a comparable effect was observed whether the steroid was added
24 hr or 10 min before the excitotoxins (Bi et al., 2000). The
discrepancies between the latter and our studies might be related to
the shorter period of exposure to the excitotoxin (Singer et al., 1996)
or to the lower dose of excitotoxin in a completely different culture
system (Bi et al., 2000).
The inefficacy of short-term pretreatment with 17 -estradiol in the
AF64A and staurosporine model for apoptosis agrees very well with the
previous findings that in the same models various antioxidants,
including melatonin, N-tert-butyl--phenylnitrone, and
dimethylthiourea, did not prevent neuronal cell death. In both models
these antioxidants prevented the initial increase of malondialdehyde,
indicating the accumulation of free radicals, but did not block the
induction of apoptosis (Harms et al., 2000).
The brain region-specific differences in the neuroprotective efficacy
of 17 -estradiol in the case of apoptotic neuronal cell death are of
considerable interest. We have observed that long-term pretreatment
with 17 -estradiol was effective only in hippocampal and septal
cultures and did not attenuate the neuronal cell death induced by AF64A
in cortical neuronal cultures. In contrast, cortical neurons pretreated
with 17 -estradiol for 1 hr became less vulnerable to excitotoxicity
or OGD, an effect that was not antagonized by tamoxifen. Thus,
receptor-independent effects of estradiol occur in cortical neurons,
whereas modulations of gene activation do not exist or do not provide
neuroprotection against AF64A in cortical cultures. One possible
explanation is the differential distribution and regulation of estrogen
receptor- and estrogen receptor- in the brain (Shughrue et al.,
1997; Laflamme et al., 1998). However, it is still a matter of debate
which estrogen receptor subtype mediates the neuroprotective efficacy
of estrogens. According to Sawada et al. (2000), estradiol provides
neuroprotection on nigral dopaminergic neurons by suppression of
proapoptotic gene transcription through the AP-1 site via activation of
estrogen receptor-. Moreover, in experimental stroke models,
estrogen receptor- deficiency does not enhance tissue damage in
female animals, suggesting that estrogen inhibits brain injury by
mechanisms that do not depend on activation of estrogen receptor-
(Sampei et al., 2000). On the other hand, several lines of evidence
support the involvement of estrogen receptor-. Evidence for a link
between estrogen receptor-, Bcl-xL expression,
and neuroprotection has been provided in cultured hippocampal neurons
(Pike, 1999). Moreover, in estrogen receptor- knock-out mice,
estradiol did not protect the brain against ischemic injury, indicating
that estrogen receptor- is a critical link in estradiol-mediated
neuroprotection (Dubal et al., 2000). Two findings of the present study
also argue for a role of estrogen receptor-. First, the lowest
immunofluorescence intensity for estrogen receptor-, but the highest
immunofluorescence intensity for estrogen receptor-, appeared in the
cortical cultures as compared with hippocampal and septal cultures.
This is in agreement with in vivo findings in the adult rat
(Shughrue et al., 1997; Laflamme et al., 1998) and confirms the recent
finding by Zhang et al. (2000) that the expression of estrogen
receptor- was barely detectable in cultured neurons from embryonic
rat cortex (E14). Second, the neuroprotectivity of 17 -estradiol was
abolished by the PI3-K inhibitor LY29402, which also has been reported
previously (Honda et al., 2000). This finding indicates a role of PI3-K
in the estradiol-mediated neuroprotection and a possible involvement of
the IGF-1 receptor pathway. This pathway is known to be activated by
estrogen receptor- but not by estrogen receptor- (Kahlert et al.,
2000). It is well established that although both estrogen receptors
exhibit the same affinity for 17 -estradiol (Kuiper et al., 1997),
the two forms of receptors display different patterns of affinities for
naturally occurring hormone response elements, suggesting a different
pattern of gene activation by the two receptors (Hyder et al., 1999).
This refers not only to the activation of IGF-1 receptor but also to
the activation of the transcription at the AP-1 sites (Paech et
al., 1997; Kahlert et al., 2000).
The ability of 17 -estradiol to modulate the expression of Bcl
proteins was demonstrated first in peripheral, non-neuronal tissue
(human breast cancer cells, in uterine endometrium during the
proliferative phase of menstrual cycle) (Bhargava et al., 1994; Otsuki
et al., 1994; Teixeira et al., 1995). In the brain, an upregulation of
Bcl-2 by estradiol was found in hypothalamic neurons of female rats
in vivo (Garcia-Segura et al., 1998). Estradiol prevents the
downregulation of Bcl-2 expression in cerebral cortex of ovariectomized
female rats induced by ischemic brain injury (Dubal et al., 1999).
Moreover, 17 -estradiol significantly increases Bcl-xL levels in cultured hippocampal neurons
(Pike, 1999). In the present study we found an increase in Bcl-2 and
Bcl-xL levels in cultured hippocampal and septal
neurons up to 68 hr after treatment with 17 -estradiol (30-100
nM), whereas the same treatment did not change
Bcl-2 and Bcl-xL levels in cortical neurons.
After treatment with AF64A an increase in Bcl-2 expression was observed in hippocampal cultures, and the effect of 17 -estradiol on Bcl-2 expression was intensified.
Although the dose range of 17 -estradiol used in the present
experiments is above the physiological and possible therapeutic range,
our data may to some extent help to explain clinical findings. In
Alzheimer's disease, where the cerebral cortex is affected as well,
the first controlled prospective clinical trial of adequate duration to
determine the benefit of estrogen did not support a role of estrogen
for the treatment of this disease (Mulnard et al., 2000). The lack of
an effect of 17 -estradiol in cortical neurons both on Bcl-2 and
Bcl-xL expression and on protection against
AF64A-induced apoptosis may provide an experimental basis for
understanding the recently reported failure to slow disease progression
in women with mild to moderate Alzheimer's disease.
| |
FOOTNOTES |
Received Nov. 7, 2000; revised Jan. 16, 2001; accepted Jan. 26, 2001.
This study was supported by Deutsche Forschungsgemeinschaft Grants INK
21/A1-1/B8 and SFB 507, by the Hermann and Lilly Schilling Stiftung, and by the Medical Faculty Charité, Humboldt University at Berlin. We are grateful to Hannelore Glatte for excellent technical assistance.
C.H. and M.L. contributed equally to this paper.
Correspondence should be addressed to Dr. Heide Hörtnagl,
Institute of Pharmacology and Toxicology, Medical Faculty
Charité, Dorotheenstrasse 94, D-10098 Berlin, Germany. E-mail:
heide.hoertnagl{at}charite.de.
| |
REFERENCES |
-
Alkayed NJ,
Murphy SJ,
Traystman RJ,
Hurn PD
(2000)
Neuroprotective effects of female gonadal steroids in reproductively senescent female rats.
Stroke
31:161-168[Abstract/Free Full Text].
-
Behl C,
Holsboer F
(1999)
The female sex hormone oestrogen as a neuroprotectant.
Trends Pharmacol Sci
20:441-444[Medline].
-
Behl C,
Skutella T,
Lezoualc'h F,
Post A,
Widmann M,
Newton CJ,
Holsboer F
(1997)
Neuroprotection against oxidative stress by estrogens: structure-activity relationship.
Mol Pharmacol
51:535-541[Abstract/Free Full Text].
-
Bertrand R,
Solary E,
O'Connor P,
Kohn KW,
Pommier Y
(1994)
Induction of a common pathway of apoptosis by staurosporine.
Exp Cell Res
211:314-321[Web of Science][Medline].
-
Beyer C,
Raab H
(1998)
Nongenomic effects of oestrogen: embryonic mouse midbrain neurones respond with a rapid release of calcium from intracellular stores.
Eur J Neurosci
10:255-262[Web of Science][Medline].
-
Bhargava V,
Kell DL,
van de Rijn M,
Warnke RA
(1994)
Bcl-2 immunoreactivity in breast carcinoma correlates with hormone receptor positively.
Am J Pathol
145:535-540[Abstract].
-
Bi R,
Broutman G,
Foy MR,
Thompson RF,
Baudry M
(2000)
The tyrosine kinase and mitogen-activated protein kinase pathways mediate multiple effects of estrogen in hippocampus.
Proc Natl Acad Sci USA
97:3602-3607[Abstract/Free Full Text].
-
Birge SJ
(1996)
Is there a role for estrogen replacement therapy in the prevention and treatment of dementia?
J Am Geriatr Soc
44:865-870[Web of Science][Medline].
-
Bonnefont AB,
Munoz FJ,
Inestrosa NC
(1998)
Estrogen protects neuronal cells from the cytotoxicity induced by acetylcholinesterase-amyloid complexes.
FEBS Lett
441:220-224[Web of Science][Medline].
-
Brewer GJ
(1995)
Serum-free B27/neurobasal medium supports differentiated growth of neurons from the striatum, substantia nigra, septum, cerebral cortex, cerebellum and dentate gyrus.
J Neurosci Res
42:674-683[Web of Science][Medline].
-
Bruer U,
Weih MK,
Isaev NK,
Meisel A,
Ruscher K,
Bergk A,
Trendelenburg G,
Wiegand F,
Victorov IV,
Dirnagl U
(1997)
Induction of tolerance in rat cortical neurons: hypoxic preconditioning.
FEBS Lett
414:117-121[Web of Science][Medline].
-
Chen Z-J,
Yu L,
Chang C-H
(1998)
Stimulation of membrane-bound guanylate cyclase activity by 17 -estradiol.
Biochem Biophys Res Commun
252:639-642[Web of Science][Medline].
-
Costa MM,
Reus VI,
Wolkowitz OM,
Manfredi F,
Lieberman M
(1999)
Estrogen replacement therapy and cognitive decline in memory-impaired post-menopausal women.
Biol Psychiatry
46:182-188[Web of Science][Medline].
-
Dubal DB,
Kashon ML,
Pettigrew LC,
Ren JM,
Finklestein SP,
Rau SW,
Wise PM
(1998)
Estradiol protects against ischemic injury.
J Cereb Blood Flow Metab
18:1253-1258[Web of Science][Medline].
-
Dubal DB,
Shughrue PJ,
Wilson ME,
Merchenthaler I,
Wise PM
(1999)
Estradiol modulates bcl-2 in cerebral ischemia: a potential role for estrogen receptors.
J Neurosci
19:6385-6393[Abstract/Free Full Text].
-
Dubal DB,
Zhu H,
Yu J,
Rau SW,
Shugrue PJ,
Merchenthaler I,
Kindy MS,
Wise PM
(2000)
Estrogen receptor alpha (ER) is critical in estradiol-mediated neuroprotection against stroke injury: insights from ER knockout (ERKO) mice.
Soc Neurosci Abstr
26:288.4.
-
Falcieri E,
Martelli AM,
Bareggi R,
Cataldi A,
Cocco L
(1993)
The protein kinase inhibitor staurosporine induces morphological changes typical of apoptosis in MOLT-4 cells without concomitant DNA fragmentation.
Biochem Biophys Res Commun
193:19-25[Web of Science][Medline].
-
Fisher A,
Mantione CR,
Abraham DJ,
Hanin I
(1982)
Long-term central cholinergic hypofunction in mice by ethylcholine aziridinium ion (AF64A) in vivo.
J Pharmacol Exp Ther
222:140-145[Abstract/Free Full Text].
-
Garcia-Segura LM,
Cardona-Gomez P,
Naftolin F,
Chowen JA
(1998)
Estradiol upregulates Bcl-2 expression in adult brain neurons.
NeuroReport
9:593-597[Web of Science][Medline].
-
Gazzaley AH,
Weiland NG,
McEwen BS,
Morrison JH
(1996)
Differential regulation of NMDAR1 mRNA and protein by estradiol in the rat hippocampus.
J Neurosci
16:6830-6838[Abstract/Free Full Text].
-
Goodman Y,
Bruce AJ,
Cheng B,
Mattson MP
(1996)
Estrogens attenuate and corticosteron exacerbates excitotoxicity, oxidative injury, and amyloid -peptide toxicity in hippocampal neurons.
J Neurochem
66:1836-1844[Web of Science][Medline].
-
Gridley KE,
Green PS,
Simpkins JW
(1997)
Low concentrations of estradiol reduce -amyloid (25-35)-induced neurotoxicity, lipid peroxidation and glucose utilization in human SK-N-SH neuroblastoma cells.
Brain Res
778:158-165[Web of Science][Medline].
-
Grodstein F,
Stampfer MJ,
Manson JE,
Colditz GA,
Willet WC,
Rosner B,
Speizer FE,
Hennekens CH
(1996)
Postmenopausal estrogen and progestin use and the risk of cardiovascular disease.
N Engl J Med
335:453-461[Abstract/Free Full Text].
-
Hanin I
(1996)
The AF64A model of cholinergic hypofunction: an update.
Life Sci
58:1955-1964[Web of Science][Medline].
-
Harms C,
Lautenschlager M,
Bergk A,
Freyer D,
Weih M,
Dirnagl U,
Weber JR,
Hörtnagl H
(2000)
Melatonin is protective in necrotic but not in caspase-dependent, free radical-independent apoptotic neuronal cell death in primary neuronal cultures.
FASEB J
14:1814-1824[Abstract/Free Full Text].
-
Honda K,
Sawada H,
Kihara T,
Urushitani M,
Nakamizo T,
Akaike A,
Shimohama S
(2000)
Phosphatidylinositol 3-kinase mediates neuroprotection by estrogen in cultured cortical neurons.
J Neurosci Res
60:321-327[Web of Science][Medline].
-
Hurn PD,
MacRae IM
(2000)
Estrogen as a neuroprotectant in stroke.
J Cereb Blood Flow Metab
20:631-652[Web of Science][Medline].
-
Hyder SM,
Chiappetta C,
Stancel GM
(1999)
Interaction of human estrogen receptors and with the same naturally occurring estrogen response elements.
Biochem Pharmacol
57:597-601[Web of Science][Medline].
-
Kahlert S,
Nuedling S,
van Eickels M,
Vetter H,
Meyer R,
Grohé C
(2000)
Estrogen receptor rapidly activates the IGF-1 receptor pathway.
J Biol Chem
24:18447-18453.
-
Keller JN,
Germeyer A,
Begley JG,
Mattson MP
(1997)
17 -Estradiol attenuates oxidative impairment of synaptic Na+/K+-ATPase activity, glucose transport, and glutamate transport induced by amyloid -peptide and iron.
J Neurosci Res
50:522-530[Web of Science][Medline].
-
Koh JY,
Choi DW
(1987)
Quantitative determination of glutamate mediated cortical neuronal injury in cell culture by lactate dehydrogenase efflux assay.
J Neurosci Methods
20:83-90[Web of Science][Medline].
-
Koh JY,
Wie MB,
Gwag BJ,
Seni SL,
Canzoniero LM,
Demaro J,
Csernansky C,
Choi DW
(1995)
Staurosporine-induced neuronal apoptosis.
Exp Neurol
135:153-159[Web of Science][Medline].
-
Kuiper GGJM,
Carlsson B,
Grandien K,
Enmark E,
Häggblad J,
Nilsson S,
Gustafsson JA
(1997)
Comparison of the ligand binding specificity and transcript tissue distribution of estrogen receptors and .
Endocrinology
138:863-870[Abstract/Free Full Text].
-
Lafferty FW,
Fiske ME
(1994)
Postmenopausal estrogen replacement: a long term cohort study.
Am J Med
97:66-77[Web of Science][Medline].
-
Laflamme N,
Nappi RE,
Drolet G,
Labrie C,
Rivest S
(1998)
Expression and neuropeptidergic characterization of estrogen receptors (ER and ER) throughout the rat brain: anatomical evidence of distinct roles of each subtype.
J Neurobiol
36:357-378[Web of Science][Medline].
-
Lautenschlager M,
Onufriev MV,
Gulyaeva NV,
Harms C,
Freyer D,
Sehmsdorf U-S,
Ruscher K,
Moiseeva YV,
Arnswald A,
Victorov I,
Dirnagl U,
Weber JR,
Hörtnagl H
(2000)
Role of nitric oxide in the ethylcholine aziridinium (AF64A) model of delayed apoptotic neurodegeneration in vivo and in vitro.
Neuroscience
97:383-393[Web of Science][Medline].
-
Mattson MP,
Robinson N,
Guo Q
(1997)
Estrogens stabilize mitochondrial function and protect neural cells against the pro-apoptotic action of mutant presenilin-1.
NeuroReport
8:3817-3821[Web of Science][Medline].
-
Mermelstein PG,
Becker JB,
Surmeier DJ
(1996)
Estradiol reduces calcium currents in rat neostriatal neurons via a membrane receptor.
J Neurosci
16:595-604[Abstract/Free Full Text].
-
Mook-Jung I,
Joo I,
Sohn S,
Kwon HJ,
Huh K,
Jung MW
(1997)
Estrogen blocks neurotoxic effects of -amyloid (1-42) and induces neurite extension on B103 cells.
Neurosci Lett
235:101-104[Web of Science][Medline].
-
Moosmann B,
Behl C
(1999)
The antioxidant neuroprotective effects of estrogens and phenolic compounds are independent from their estrogenic properties.
Proc Natl Acad Sci USA
96:8867-8872[Abstract/Free Full Text].
-
Mulnard RA,
Cotman CW,
Kawas C,
van Dyck CH,
Sano M,
Doody R,
Koss E,
Pfeiffer E,
Jin S,
Gamst A,
Grundman M,
Thomas R,
Thal LJ
(2000)
Estrogen replacement therapy for treatment of mild to moderate Alzheimer's disease. A randomized controlled trial.
JAMA
283:1007-1015[Abstract/Free Full Text].
-
Nath R,
Raser KJ,
Stafford D,
Hajimohammadreza I,
Posener A,
Allen H,
Talanian RV,
Yuen P,
Gilbertsen RB,
Wang KK
(1996)
Non-erythroid -spectrin breakdown by calpain and interleukin 1 -converting-enzyme-like protease(s) in apoptotic cells: contributory roles of both protease families in neuronal apoptosis.
Biochem J
319:683-690.
-
Otsuki Y,
Misaki O,
Sugimoto O,
Ito Y,
Tsujimoto Y,
Akao Y
(1994)
Cyclic bcl-gene expression in humane uterine endometrium during menstrual cycle.
Lancet
344:28-29[Web of Science][Medline].
-
Paech K,
Webb P,
Kuiper GGJM,
Nilsson S,
Gustafsson J-A,
Kushner PJ,
Scanlan TS
(1997)
Differential ligand activation of estrogen receptors ER and ER at AP1 site.
Nature
277:1508-1510.
-
Paganini-Hill A,
Henderson VW
(1994)
Estrogen deficiency and risk of Alzheimer's disease in women.
Am J Epidemiol
140:256-261[Abstract/Free Full Text].
-
Pike CJ
(1999)
Estrogen modulates neuronal Bcl-xL expression and -amyloid-induced apoptosis: relevance to Alzheimer's disease.
J Neurochem
72:1552-1563[Web of Science][Medline].
-
Raff MC,
Barres B,
Burne J,
Coles H,
Ishizaki Y,
Jacobson M
(1993)
Programmed cell death and control of cell survival: lessons from the central nervous system.
Science
262:695-700[Abstract/Free Full Text].
-
Regan RF,
Guo Y
(1997)
Estrogens attenuate neuronal injury due to hemoglobin, chemical hypoxia, and excitatory amino acids in murine cortical cultures.
Brain Res
764:133-140[Web of Science][Medline].
-
Rinner WA,
Pifl C,
Lassmann H,
Hörtnagl H
(1997)
The induction of apoptosis in vitro and in vivo by the cholinergic neurotoxin ethylcholine aziridinium.
Neuroscience
79:535-542[Web of Science][Medline].
-
Robinson D,
Friedman L,
Marcus R,
Tinklenberg J,
Yesavage J
(1994)
Estrogen replacement therapy and memory in older women.
J Am Geriatr Soc
42:919-922[Web of Science][Medline].
-
Sampei K,
Goto S,
Alkayed NJ,
Crain BJ,
Korach KS,
Traystman RJ,
Demas GE,
Nelson RJ,
Hurn PD
(2000)
Stroke in estrogen receptor--deficient mice.
Stroke
31:738-744[Abstract/Free Full Text].
-
Sawada H,
Ibi M,
Kihara T,
Urushitani M,
Akaike A,
Shimohama S
(1998)
Estradiol protects mesencephalic dopaminergic neurons from oxidative stress-induced neuronal death.
J Neurosci Res
54:707-719[Web of Science][Medline].
-
Sawada H,
Ibi M,
Kihara T,
Urushitani M,
Honda K,
Nakanishi M,
Akaike A,
Shimohama s
(2000)
Mechanisms of antiapoptotic effects of estrogens in nigral dopaminergic neurons.
FASEB J
14:1202-1214[Abstract/Free Full Text].
-
Sherwin BB
(1994)
Estrogenic effects on memory in women.
Ann NY Acad Sci
743:213-230[Web of Science][Medline].
-
Shi J,
Panickar KS,
Yang S-H,
Rabbani O,
Day AL,
Simpkins JW
(1998)
Estrogen attenuates over-expression of -amyloid precursor protein messenger RNA in an animal model of focal ischemia.
Brain Res
810:87-92[Web of Science][Medline].
-
Shughrue PJ,
Lane MV,
Merchenthaler I
(1997)
Comparative distribution of estrogen receptor- and - mRNA in the rat central nervous system.
J Comp Neurol
388:507-525[Web of Science][Medline].
-
Singer CA,
Rogers KL,
Strickland TM,
Dorsa DM
(1996)
Estrogen protects primary cortical neurons from glutamate toxicity.
Neurosci Lett
212:13-16[Web of Science][Medline].
-
Singer CA,
Figueroa-Masot XA,
Batchelor RH,
Dorsa DM
(1999)
The mitogen-activated protein kinase pathway mediates estrogen neuroprotection after glutamate toxicity in primary cortical neurons.
J Neurosci
19:2455-2463[Abstract/Free Full Text].
-
Tang M-X,
Jacobs D,
Stern Y,
Marder K,
Schofield P,
Gurland B,
Andrews H,
Mayeux R
(1996)
Effect of oestrogen during menopause on risk and age at onset of Alzheimer's disease.
Lancet
348:429-432[Web of Science][Medline].
-
Teixeira C,
Reed JC,
Pratt MA
(1995)
Estrogen promotes chemotherapeutic drug resistance by a mechanism involving Bcl-2 proto-oncogene expression in human breast cancer cells.
Cancer Res
55:3902-3907[Abstract/Free Full Text].
-
Wang KKW
(2000)
Calpain and caspase: can you tell the difference?
Trends Neurosci
23:20-26[Web of Science][Medline].
-
Weaver Jr CE,
Park-Chung M,
Gibbs TT,
Farb DH
(1997)
17 -Estradiol protects against NMDA-induced excitotoxicity by direct inhibition of NMDA receptors.
Brain Res
761:338-341[Web of Science][Medline].
-
Wiesner DA,
Dawson G
(1996)
Staurosporine induces programmed cell death in embryonic neurons and activation of the ceramide pathway.
J Neurochem
66:1418-1425[Web of Science][Medline].
-
Xu H,
Gouras GK,
Greenfield JP,
Vincent B,
Naslund J,
Mazzarelli L,
Fried G,
Jovanovic JN,
Seeger M,
Relkin NR,
Liao F,
Checler F,
Buxbaum JD,
Chait BT,
Thinakaran G,
Sisodia SS,
Wang R,
Greengard P,
Gandy S
(1998)
Estrogen reduces neuronal generation of Alzheimer -amyloid peptides.
Nat Med
4:447-451[Web of Science][Medline].
-
Yaffe K,
Sawaya G,
Lieberburg I,
Grady D
(1998)
Estrogen therapy in postmenopausal women: effects on cognitive function and dementia.
JAMA
279:688-695[Abstract/Free Full Text].
-
Zaulyanov LL,
Green PS,
Simpkins JW
(1999)
Glutamate requirement for neuronal death from anoxia-reoxygenation: an in vitro model for assessment of the neuroprotective effects of estrogens.
Cell Mol Neurobiol
19:705-718[Web of Science][Medline].
-
Zhang L,
Chang YH,
Barker JL,
Hu Q,
Zhang L,
Maric D,
Li B-S,
Rubinow DR
(2000)
Testosterone and estrogen affect neuronal differentiation but not proliferation in early embryonic cortex of the rat: the possible roles of androgen and estrogen receptors.
Neurosci Lett
281:57-60[Web of Science][Medline].
Copyright © 2001 Society for Neuroscience 0270-6474/01/2182600-10$05.00/0
This article has been cited by other articles:
|
|
|
|
 
O. Hoffmann, J. S. Braun, D. Becker, A. Halle, D. Freyer, E. Dagand, S. Lehnardt, and J. R. Weber
TLR2 Mediates Neuroinflammation and Neuronal Damage
J. Immunol.,
May 15, 2007;
178(10):
6476 - 6481.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Harms, K. Albrecht, U. Harms, K. Seidel, L. Hauck, T. Baldinger, D. Hubner, G. Kronenberg, J. An, K. Ruscher, et al.
Phosphatidylinositol 3-Akt-Kinase-Dependent Phosphorylation of p21Waf1/Cip1 as a Novel Mechanism of Neuroprotection by Glucocorticoids
J. Neurosci.,
April 25, 2007;
27(17):
4562 - 4571.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Yao, T.-V. V. Nguyen, and C. J. Pike
Estrogen Regulates Bcl-w and Bim Expression: Role in Protection against {beta}-Amyloid Peptide-Induced Neuronal Death
J. Neurosci.,
February 7, 2007;
27(6):
1422 - 1433.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. H. Herynk, A. R. Beyer, Y. Cui, H. Weiss, E. Anderson, T. P. Green, and S. A.W. Fuqua
Cooperative action of tamoxifen and c-Src inhibition in preventing the growth of estrogen receptor-positive human breast cancer cells
Mol. Cancer Ther.,
December 1, 2006;
5(12):
3023 - 3031.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Fillon, K. Soulis, S. Rajasekaran, H. Benedict-Hamilton, J. N. Radin, C. J. Orihuela, K. C. El Kasmi, G. Murti, D. Kaushal, M. W. Gaber, et al.
Platelet-Activating Factor Receptor and Innate Immunity: Uptake of Gram-Positive Bacterial Cell Wall into Host Cells and Cell-Specific Pathophysiology
J. Immunol.,
November 1, 2006;
177(9):
6182 - 6191.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. B. J. Morales, K. K. Loo, H.-b. Liu, C. Peterson, S. Tiwari-Woodruff, and R. R. Voskuhl
Treatment with an estrogen receptor alpha ligand is neuroprotective in experimental autoimmune encephalomyelitis.
J. Neurosci.,
June 21, 2006;
26(25):
6823 - 6833.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. B. Dubal, S. W. Rau, P. J. Shughrue, H. Zhu, J. Yu, A. B. Cashion, S. Suzuki, L. M. Gerhold, M. B. Bottner, S. B. Dubal, et al.
Differential Modulation of Estrogen Receptors (ERs) in Ischemic Brain Injury: A Role for ER{alpha} in Estradiol-Mediated Protection against Delayed Cell Death
Endocrinology,
June 1, 2006;
147(6):
3076 - 3084.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. D. Hilton, L. L. Bambrick, S. M. Thompson, and M. M. McCarthy
Estradiol Modulation of Kainic Acid-Induced Calcium Elevation in Neonatal Hippocampal Neurons
Endocrinology,
March 1, 2006;
147(3):
1246 - 1255.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. A. Schreihofer, K. D. Do, and A. M. Schreihofer
High-soy diet decreases infarct size after permanent middle cerebral artery occlusion in female rats
Am J Physiol Regulatory Integrative Comp Physiol,
July 1, 2005;
289(1):
R103 - R108.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. A. Sortino, M. Chisari, S. Merlo, C. Vancheri, M. Caruso, F. Nicoletti, P. L. Canonico, and A. Copani
Glia Mediates the Neuroprotective Action of Estradiol on {beta}-Amyloid-Induced Neuronal Death
Endocrinology,
November 1, 2004;
145(11):
5080 - 5086.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. Du, H. Bayir, Y. Lai, X. Zhang, P. M. Kochanek, S. C. Watkins, S. H. Graham, and R. S. B. Clark
Innate Gender-based Proclivity in Response to Cytotoxicity and Programmed Cell Death Pathway
J. Biol. Chem.,
September 10, 2004;
279(37):
38563 - 38570.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. K. Murashov, R. R. Islamov, R. J. McMurray, E. S. Pak, and D. A. Weidner
Estrogen increases retrograde labeling of motoneurons: evidence of a nongenomic mechanism
Am J Physiol Cell Physiol,
August 1, 2004;
287(2):
C320 - C326.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. S. Soldan, A. I. A. Retuerto, N. L. Sicotte, and R. R. Voskuhl
Immune Modulation in Multiple Sclerosis Patients Treated with the Pregnancy Hormone Estriol
J. Immunol.,
December 1, 2003;
171(11):
6267 - 6274.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. W. Singleton, Y. Feng, C. J. Burd, and S. A. Khan
Nongenomic Activity and Subsequent c-fos Induction by Estrogen Receptor Ligands Are Not Sufficient to Promote Deoxyribonucleic Acid Synthesis in Human Endometrial Adenocarcinoma Cells
Endocrinology,
January 1, 2003;
144(1):
121 - 128.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. F. Rissman, A. L. Heck, J. E. Leonard, M. A. Shupnik, and J.-A. Gustafsson
Disruption of estrogen receptor beta gene impairs spatial learning in female mice
PNAS,
March 19, 2002;
99(6):
3996 - 4001.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
TOP
ABSTRACT
INTRODUCTION
