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The Journal of Neuroscience, May 15, 2002, 22(10):3898-3909
Transforming Growth Factor-
1 Increases Bad Phosphorylation and
Protects Neurons Against Damage
Yuan
Zhu1,
Guo-Yuan
Yang3,
Barbara
Ahlemeyer1,
Li
Pang3,
Xiao-Ming
Che3,
Carsten
Culmsee1,
Susanne
Klumpp2, and
Josef
Krieglstein1
Institut für 1 Pharmakologie und Toxikologie and
2 Pharmazeutische Chemie, Philipps-Universität,
D-35032 Marburg, Germany, and 3 Department of Surgery,
University of Michigan, Ann Arbor, Michigan 48109
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ABSTRACT |
Despite the characterization of neuroprotection by transforming
growth factor-
1 (TGF-1), the signaling pathway mediating its
protective effect is unclear. Bad is a proapoptotic member of the Bcl-2
family and is inactivated on phosphorylation via mitogen-activated
protein kinase (MAPK). This study attempted to address whether MAPK
signaling and Bad phosphorylation were influenced by TGF-1 and,
furthermore, whether these two events were involved in the
antiapoptotic effect of TGF-1. We found a gradual activation of
extracellular signal-regulated kinase 1/2 (Erk1/2) and MAPK-activated
protein kinase-1 (also called Rsk1) and a concomitant increase in Bad
phosphorylation at Ser112 in mouse brains after
adenovirus-mediated TGF-1 transduction under nonischemic and
ischemic conditions induced by transient middle cerebral artery
occlusion. Consistent with these effects, the ischemia-induced increase
in Bad protein level and caspase-3 activation were suppressed in
TGF-1-transduced brain. Consequently, DNA fragmentation, ischemic
lesions, and neurological deficiency were significantly reduced. In
cultured rat hippocampal cells, TGF-1 inhibited the increase in Bad
expression caused by staurosporine. TGF-1 concentration- and
time-dependently activated Erk1/2 and Rsk1 accompanied by an increase
in Bad phosphorylation. These effects were blocked by U0126, a
mitogen-activated protein kinase/Erk kinase 1/2 inhibitor,
suggesting an association between Bad phosphorylation and MAPK
activation. Notably, U0126 and a Rsk1 inhibitor (Ro318220) abolished the neuroprotective activity of TGF-1 in
staurosporine-induced apoptosis, indicating that activation of MAPK is
necessary for the antiapoptotic effect of TGF-1 in cultured
hippocampal cells. Together, we demonstrate that TGF-1 suppresses
Bad expression under lesion conditions, increases Bad phosphorylation,
and activates the MAPK/Erk pathway, which may contribute to its
neuroprotective activity.
Key words:
TGF-1; neuroprotection; MAPK/Erk signaling; Bad
phosphorylation; cerebral ischemia; rat hippocampal cells
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INTRODUCTION |
Transforming growth factor-1
(TGF-1) is a multifunctional cytokine capable of regulating diverse
cellular processes. The neuroprotective effect of TGF-1 in
vitro (Krieglstein and Krieglstein, 1997
) has been related to its
ability to maintain the mitochondrial membrane potential, to stabilize
Ca2+ homeostasis, to increase the
expression of the anti-apoptotic proteins Bcl-2 and Bcl-xl (Prehn et
al., 1994), to inhibit caspase-3 activation (Zhu et al., 2001), and to
induce plasminogen activator inhibitor-1 (Buisson et al., 1998).
TGF-1 has also been shown to reduce brain damage after either
ischemic (Henrich-Noack et al., 1996; Flanders et al., 1998; Pang et
al., 2001) or excitotoxic injury (Ruocco et al., 1999). However, the
signaling pathway underlying the neuroprotective effect of TGF-1
remains unclear.
TGF-1 has been suggested to mediate signaling from the cell membrane
to the nucleus through the activation of TGF- type II receptors and
subsequent activation of type I receptors, which in turn phosphorylates
the Smad protein family (Massagué, 2000). However, recent data
indicated the involvement of mitogen-activated protein kinase (MAPK) in
TGF-1 signaling. Activation of the Ras-MAPK cascade was shown to be
necessary for multiple functions of TGF-1 in kidney and
epithelial cells (Chio, 2000; Mulder, 2000). Chin et al. (1999)
reported that TGF-1 rescued macrophages from apoptosis via the
MAPK/extracellular signal-regulated kinase (Erk) pathway. Thus, it is
of high interest to investigate whether MAPK/Erk signaling can be
activated by TGF-1 in brain tissue and in cultured neurons and
whether MAPK activation contributes to the neuroprotective effect of
TGF-1.
Bad, a proapoptotic member of the Bcl-2 family, is inactivated on
phosphorylation, which creates consensus sites for Bad to interact with
14-3-3 proteins instead of Bcl-xl and Bcl-2, resulting in the
liberation of these antiapoptotic proteins (Yang et al., 1995; Zha et
al., 1996; Scheid et al., 1999). So far, four sites on Bad,
Ser112,
Ser136,
Ser155, and
Ser170, have been reported to be
phosphorylated in response to different stimuli (Lizcano et al., 2000,
Dramsi et al., 2002). In particular, Ser112 could be phosphorylated on
activation of MAPK/Erk signaling (Fang et al., 1999; Shimamura et al.,
2000). Rsk1 is an immediate downstream target of Erk1/2 and
phosphorylates Bad. Moreover, Bad phosphorylation is required for the
cell survival-promoting effect mediated by Rsk1 (Bonni et al., 1999;
Fang et al., 1999; Shimamura et al., 2000). Interestingly, the
survival-promoting effects of epidermal growth factor (EGF), BDNF, and
interleukin-3 (IL-3) are associated with phosphorylation of Bad at
Ser112 via activation of MAPK/Erk1/2
(Downward, 1999).
The present study aims to investigate whether TGF-1 can activate the
MAPK/Erk1/2 cascade and, if so, whether Bad is subsequently phosphorylated and, furthermore, whether these events contribute to the
neuroprotective effect of TGF-1.
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MATERIALS AND METHODS |
Vector construction and intracerebral injection. The
construction of a human adenovirus serotype 5-derived adenoviral vector that transduces Escherichia coli -galactosidase
(AdRSVlacZ) was performed as described previously (Pang et al., 2001).
A recombinant replication-defective (E1, E3 deleted) adenoviral
serotype 5 vector (AdRSV) was constructed for the overexpression of
active human TGF-1 (ahTGF-1). The human TGF-1 cDNA was
generated as described previously (Arrick et al., 1992), and both 5'
and 3' ends of cDNA were modified by using NotI linkers. The
plasmid AdRSVahTGF-1 (pAdRSVahTGF-1) was then used to produce
recombinant adenoviral clones. Individual clones of pAdRSVahTGF-1
were isolated and purified by CsCl banding and desalting through
Sephadex G50. High-titer stocks were stored at 
20°C in PBS
containing 5% glycerol and diluted with PBS immediately before use.
Mature male CD-1 mice (Charles River Laboratories, Wilmington, MA)
weighing 30-35 gm were anesthetized with 4% chloral
hydrate (400 mg/kg, i.p.), and then placed in a stereotactic frame with
a mouse holder (model 921; David Kopf Instruments, Tujunga, CA). A burr
hole was drilled in the right pericranium 1 mm lateral to the sagittal
suture and 1 mm posterior to the coronal suture. A 28 gauge needle
affixed to a Hamilton (Reno, NV) syringe was slowly inserted into the right lateral ventricle (3.0 mm deep from dura). An adenoviral suspension (1 µl) containing 1 × 1012 virus particles/ml was
injected into the lateral ventricle at a rate of 0.2 µl/min. Control animals received the same amount of saline or
AdRSVlacZ at the same injection rate. The needle was then withdrawn
slowly. The hole was sealed with bone wax, and the wound was closed
with a suture. The animals were allowed to recover in their cages.
TGF-1 ELISA. Mice were anesthetized as described above,
and their brains were removed from nontransduced control mice and from
TGF-1-transducd mice at defined time points. Blood plasma samples
were collected at the same time from each animal. These brain and blood
samples were quickly frozen in liquid nitrogen until performance of
ELISA. After sonication and centrifugation of probes at 30,000 × g for 30 min, the supernatants were collected for
measurement of TGF-1 concentration by using a TGF-1 ELISA kit (R
& D Systems, Minneapolis, MN). The detection was done under acidified
conditions according to the manufacturer's protocol, thereby
representing the total levels of TGF-1. Absorbance of the peroxidase
reaction product was measured at 450 nm excitation wavelength.
Recombinant human TGF-1 was used for establishing the standard curve.
Transient middle cerebral artery occlusion and infarct volume
assay. On the fifth day after either AdRSVahTGF-1, AdRSVlacZ, or saline injection, the mice were anesthetized with 1.5% isoflurane in 70/30% N2O/O2. A PE-10
catheter was introduced into the left femoral artery for continuous
monitoring of arterial blood pressure, sampling of blood gases, and pH
analysis before and during ischemia. Rectal temperature was controlled
at 37.0 ± 0.5°C with a regulated heating pad (model 73ATD
indicating controller; Yellow Springs Instrument Co., Yellow Springs,
OH). The internal carotid artery was isolated, and the pterygopalatine
artery was ligated. A 2 cm length of a 5-0 rounded nylon suture with a
slightly larger tip was gently advanced from the external carotid
artery to the beginning of the middle cerebral artery for a distance of
10.0 ± 0.5 mm. After 30 min of occlusion, the suture was
partially withdrawn from the internal carotid artery to the common
carotid artery. Cerebral ischemia was confirmed by monitoring the
surface cerebral blood flow using a laser Doppler flow meter (BPM2
system; Vasamedics Inc., St. Paul, MN) as described previously (Yang et al., 1994).
Mouse brains were removed 1 d after transient middle cerebral
artery occlusion and frozen immediately in 2-methylbutane at 42°C for
5 min. Cryostat sections (20 µm thickness) were cut and then stained
with cresyl violet. Using NIH Image 1.62 software, the lesioned area
was measured and calculated as the difference in area of the
contralateral (nonischemic) hemisphere and the normal area of the
ipsilateral (ischemic) hemisphere. The ischemic lesion was obtained
from multiplying the lesioned areas by the thickness of the sections.
Evaluation of neurological deficiency (beam test). Fine
motor coordination was evaluated according to the protocol described by
Aronowski et al. (1996) with some modifications. The mouse was placed
on one end of a narrow wooden beam (8 mm in width and 600 mm in length)
which was fixed 300 mm above a 60-mm-thick foam pad. The time of foot
faults for the right hindlimb over 50 steps was counted in either
direction on the beam. A baseline level of competence at this task was
established before surgery with an acceptance level of <10 faults per
50 steps. Mice were examined before adenoviral vector injections before
and 24 hr after transient middle cerebral artery occlusion (tMCAO).
Terminal deoxynucleotidyl transferase-mediated dUTP nick end
labeling. The mice were anesthetized 1 d after tMCAO and
transcardially perfused with 4% paraformaldehyde in PBS. The brains
were removed, and coronal paraffin sections (5 µm thickness) were cut
from the striatum for the evaluation of cellular DNA fragmentation
in situ. Terminal deoxynucleotidyl transferase-mediated dUTP
nick end-labeling staining was performed using an ApoTag kit (Oncor,
Gaithersburg, MD) according to the previous protocol (Zhu et al.,
1998). Sections were then analyzed using a confocal laser scanning
microscope (Zeiss, Jena, Germany). The numbers of TUNEL-positive cells
were counted in four different fields with the size of 326 × 326 µm in the ipsilateral side of each animal. Three mice were used in each group.
Immunocytochemistry. Coronal paraffin sections
were prepared 8 hr after tMCAO as described above. After
deparaffinization and permeabilization, sections were incubated with
blocking buffer containing 2% bovine serum albumin (BSA) and 10%
normal goat serum for 1 hr at 37°C. Rabbit anti-TGF-1 (1:20; Santa
Cruz Biotechnology, Heidelberg, Germany), rabbit anti-phospho-Erk1/2
(P-Erk1/2, 1:200; Cell Signaling Technology, Frankfurt, Germany), mouse
anti-Bad (phospho-independent, 1:300; Transduction Laboratories,
Heidelberg, Germany), and rabbit anti-active caspase-3 antibody (1:400;
Transduction Laboratories) were applied to the sections overnight at
4°C. As negative controls, sections were incubated with
an identical concentration of nonspecific mouse or rabbit IgG1 instead
of primary antibody. After washing the sections with washing buffer
[1% BSA in Tris-buffered saline (TBS)], biotin-conjugated anti-mouse
or anti-rabbit IgG was added to the sections, followed by incubation
with fluorescein-avidin D. For double staining, the sections were
incubated with mouse anti-Bad and rabbit anti-neurofilament 200 (1:200;
Sigma, Deisenhofen, Germany) antibodies, mouse anti-Bad and rabbit
anti-caspase-3 antibodies, rabbit anti-TGF-1 and mouse anti-Bad
antibodies, rabbit anti-P-Erk1/2 and mouse anti-neuron-specific enolase
(NSE) antibodies (1:100; Capricorn, Scarborough, ME), or rabbit
anti-P-Erk1/2 and mouse anti-glia fibrillary acidic protein
(GFAP) antibodies (1:100; Santa Cruz Biotechnology, Santa Cruz,
CA). The sections were subsequently incubated with biotin-conjugated
anti-mouse or anti-rabbit IgG followed by the fluorescein-avidin D
reaction. Thereafter, a rhodamine-conjugated anti-rabbit or anti-mouse
IgG was applied to the sections. Finally, the sections were mounted with a mounting medium (Dako, Hamburg, Germany) and analyzed by confocal laser scanning microscopy.
Western blotting. The mice were deeply anesthetized, and the
striatum was quickly removed. The brain tissue was homogenized by
sonication in a lysis buffer containing 10% glycerol, 3% sodium lauryl sulfate, 0.5 M Tris, 1 mM
phenylmethylsulfonyl fluoride, 1 µM calpain inhibitor I,
and 7 µg/ml trypsin inhibitor. Lysates were centrifuged at
20,000 × g (4°C) for 20 min, and the supernatants were collected for protein concentration assay using a BCA kit (Pierce,
Rockford, IL). Samples containing an equal amount of total protein were
loaded on 12.5 or 15% SDS-polyacrylamide gels. After electrophoresis,
the proteins were transferred onto a nitrocellulose membrane. The
protein transfer was controlled by staining with Ponceau S. Unspecific
binding was blocked by a buffer containing 0.1% Tween 20, 2% BSA, and
5% nonfat dry milk in TBS. The blots were then incubated with primary
antibodies diluted in blocking buffer overnight at 4°C. The following
antibodies were used for Western blotting: phospho-specific anti-rabbit
Erk1/2, phospho-specific anti-rabbit Rsk1
(Thr360/Ser364),
phospho-specific anti-rabbit Bad (Ser112,
1:1000; Cell Signaling Technology), anti-mouse Bad (1:300), anti-rabbit
antibody against both pro- and active caspase-3 (1:400; Santa Cruz
Biotechnology), and anti-mouse 
-tubulin (1:2000; Sigma). After
washing the membranes with 0.1% Tween 20 in TBS, the blots were
incubated with horseradish peroxidase-conjugated anti-mouse or
anti-rabbit IgG (1:2500) at room temperature for 1 hr. Peroxidase activity was detected by the Amersham Biosciences (Arlington Heights, IL) ECL detection system. To control the amount of protein loaded in
the each lane, -tubulin was detected in parallel. The integrated optical density (IOD) of the signals was semiquantified and expressed as the ratio of IOD from the tested proteins to IOD from -tubulin. Data were given as means ± SD of the percentage ratio of the control.
Primary rat hippocampal cultures. Mixed primary rat
hippocampal cultures were prepared as described previously (Zhu et al., 2001). Briefly, the hippocampi from neonatal Fischer 344 rats (postnatal days 1-2) were dissected and incubated for 20 min in Leibovitz's L15 medium supplemented with 1 mg/ml papain and 0.2 mg/ml
BSA. Thereafter, the cell suspension was layered onto growth medium
containing 1% trypsin inhibitor and 10% BSA. After centrifugation at
200 × g for 10 min, the pellet was resuspended and
seeded into poly-L-lysine-coated Petri dishes
with a density of 2-3 × 104
cells/cm2. The cells were cultured in
neurobasal medium with 0.5 mM glutamine, B27
supplement, and antibiotics for 8 d.
Drug treatment. TGF-1 (R & D Systems, Wiesbaden, Germany)
was administered to the cells on the seventh day of the culture. To
induce apoptosis, staurosporine was added to the cells at a final
concentration of 100 nM in the absence of TGF-1 or 24 hr after the onset of TGF-1 treatment. In some experiments, U0126 at a
final concentration of 10 or 20 µM (Cell Signaling
Technology) or Ro318220 at the final concentration of 5 or 10 µM (Cell Signaling Technology) was added to the cells 2 hr before the TGF-1 treatment to block the activation of MAPK.
Control cultures received vehicle only. There were four series of
experiments designed for cultured hippocampal cells: (1) the
concentration-dependent effect of TGF-1 on the activation of MAPK
and on the phosphorylation of Bad was established, in which cultured
cells received 0.1, 1.0, and 10 ng/ml TGF-1 and were harvested 8 hr
after the onset of the treatment for Western blot analysis; (2) to
evaluate the time-dependent effect of TGF-1 on the activation of
MAPK and phosphorylation of Bad, the cells were treated with 10 ng/ml
TGF-1 and collected 15 and 30 min and 1, 8, and 24 hr after the
treatment; (3) to find out whether TGF-1 modulates Bad protein
expression, cells were harvested at 6 and 24 hr after the exposure to
staurosporine in the absence or presence of TGF-1 (1 and 10 ng/ml)
for Western blot analysis; and (4) to reveal the role of MAPK
activation in the antiapoptotic effect of TGF-, apoptosis was
evaluated by the nuclear staining 24 hr after the exposure of
staurosporine in the absence and in the presence of TGF-1 (10 ng/ml). Using the same treatment protocol, the cells were harvested for
Western blot analysis to study the activation of MAPK and Bad
phosphorylation in parallel.
Nuclear staining. Cells were fixed with methanol and
incubated with Hoechst 33258 (10 µg/ml; Sigma) at 37°C for 10 min,
followed by washing with methanol and PBS. Thereafter, the nuclear
morphology was analyzed under the fluorescence microscope. Cells
showing condensed chromatin or fragmented nuclei were counted as
apoptotic cells, and the data were given as the means ± SD of the
percentage of apoptotic cells.
Statistics. All data were expressed as means ± SD.
ANOVA followed by Scheffé's test was used in Figures
1A, 3, B and C, and 9,
A and C. Student's t test was used in
Figures 2D, c, 4B, 5B, 6B, 7, A and B, and 8,
B and D.
| |
RESULTS |
Adenovirus-mediated TGF-1 transduction increased TGF-1 level
in mouse brain
The levels of TGF-1 protein in the brain and in the blood
plasma were measured in normal mice (nontransduced) and immediately (0 d) and 1, 3, 5, 7, 10, 14, and 21 d after cerebral TGF-1
transduction. TGF-1 levels were very low in brain tissue of
nontransduced mice and immediately after transduction (0 d, ~23 pg/gm
of brain tissue). TGF-1 levels gradually increased from day 3 to day
7 after transduction. The level of TGF-1 in mouse brain tissue
peaked at 7 d after transduction (1395 ± 258 pg/gm of brain
tissue) and was maintained at higher levels up to 10 d after
transduction. It was then declined nearly to the basal level 14 d
after adenoviral injection (Fig. 1A). The basal
concentration of TGF-1 in blood plasma of nontransduced mice was
1683 ± 611 pg/ml, which was much higher than that in brain tissue
of nontransduced mice. There were no significant changes in plasma
levels of TGF-1 up to 21 d after TGF-1 transduction, indicating that cerebral transduction of TGF-1 did not influence the
level of TGF-1 in the blood (data not shown).
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Figure 1.
Adenovirus transduction causes an increase in
TGF-1 and P-Erk1/2 levels in mouse brain tissue. A,
Time course of TGF-1 concentration detected in mouse brain tissue.
Adenovirus carrying the human active TGF-1 gene was injected into
the lateral ventricle of the mice. The brains were removed immediately
(0 d) and 1, 3, 5, 7, 10, 14, and 21 d after adenoviral injection. TGF-1 concentration was measured
by ELISA under acidified conditions, thereby representing the total
level of TGF-1. ***p < 0.001 compared with
0 d. Data are expressed as means ± SD from five mice for
each time point. B, Immunostaining of TGF-1 in the
cortex (b, c) and the striatum (d, e)
5 d after lacZ (b, d) or TGF-1 (c,
e) transduction. C, Immunostaining of P-Erk1/2
in the cortex (b, c) and the striatum (d,
e) 5 d after lacZ (b, d) or TGF-1
(c, e) transduction. Negative controls of TGF-1 and
P-Erk1/2 immunostaining are shown in B, a, and C,
a, respectively. Scale bars, 20 µm.
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We further studied the distribution of TGF-1 in brain tissue 5 d after either lacZ or TGF-1 transduction by immunostaining. A
negative control did not show detectable immunofluorescence (Fig.
1B, a). TGF-1 immunoreactivity was considerably
increased in both the extracellular matrix and neuronal cytoplasm of
cortical (Fig. 1B, c) and striatal (Fig.
1B, e) regions of TGF-1-transduced mice in
comparison with lacZ-transduced mice (Fig. 1B, b, d). The TGF-1 level seemed to be particularly high in the cytoplasm and
in the striatal fibers. In addition, a high level of TGF-1 protein
was detected in the region surrounding cerebral vessels in
TGF-1-transduced brain.
Overexpression of TGF-1 interfered with apoptotic cascades,
attenuated brain damage, and improved the neurological outcome after
tMCAO
Physiological parameters including the animal's body temperature,
blood pressure, blood PO2,
PCO2, and pH were controlled at normal levels
during and after tMCAO. These parameters and surface cerebral blood
flow did not differ among TGF-1-transduced-, lacZ-, and
saline-injected mice (data not shown).
To determine whether ischemia-activated apoptotic cascades could be
suppressed by TGF-1 transduction, immunostaining of Bad and active
caspase-3 was performed in brain sections 8 hr after tMCAO. There was
no visible fluorescence in negative control sections (Fig.
2A, g). Enhanced Bad
immunoreactivity was detected in the ipsilateral striatum (Fig.
2A, b) accompanied by a significant activation of
caspase-3 (Fig. 2A, e), whereas Bad immunoreactivity was only weakly visible (Fig. 2A, a), and no active
caspase-3 (Fig. 2A, d) was seen in the contralateral
side. Double staining indicated colocalization of Bad with the neuronal
marker neurofilament 200 (Fig. 2B, a-c), as well as
colocalization of Bad with active caspase-3 (Fig. 2B,
d-f). The ischemia-induced increase in Bad immunoreactivity and activation of caspase-3 were inhibited in TGF-1-transduced mice, as shown in Figure 2A, c
and f, respectively. Furthermore, it was noted that cells in
the ischemic penumbra highly expressing TGF-1 showed normal
morphology (Fig. 2C, a, arrowhead) where Bad
immunoreactivity in these cells appeared considerably weak (Fig.
2C, b, arrowhead). In contrast, increased Bad
immunoreactivity was seen in the damaged cells, which showed reduced
expression of TGF-1 (Fig. 2C, arrows). These findings were in agreement with the results obtained from Western blot analysis
(see Fig. 5A, fourth and fifth panels).
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Figure 2.
Overexpression of TGF-1 inhibits the expression
of Bad, the activation of caspase-3, and DNA fragmentation in ischemic
brain after 30 min of MCAO. A, Immunostaining of Bad
(a-c) and active caspase-3 (d-f)
in striatal sections prepared 8 hr after reperfusion. Only weak Bad
immunoreactivity was detected in the contralateral side
(a), whereas it markedly increased in the
ipsilateral side (b) of control mice, which were
subjected to intracerebral lacZ injection. In comparison, activation of
caspase-3 was not detected in the contralateral side
(d) but was clearly visible in the ipsilateral
side (e) of control mice. TGF-1 transduction
inhibited both Bad expression (c) and caspase-3
activation (f) in the ipsilateral side. Negative
controls did not show detectable immunofluorescence
(g). Scale bar, 10 µm. B, Double
staining of a striatum section prepared 8 hr after cerebral ischemia.
a-c, Double staining of Bad and neurofilament 200. Bad
immunoreactivity (a) was colocalized with the
neuronal marker neurofilament 200 (b), as
evidenced by the overlap image (c).
d-f, Double staining of Bad and active caspase-3. Bad
immunoreactivity (d) was colocalized with active
caspase-3 (e), as revealed by the overlap image
(f). The immunostaining was reproduced in three
mice per group. Scale bar, 20 µm. C, Double staining
of TGF-1 (a) and Bad (b)
in the penumbra of a lesioned area 8 hr after tMCAO. TGF-1
immunoreactivity was detected in the extracellular matrix and in the
cytoplasma of cells with normal morphology and very low Bad
immunoreactivity (arrowhead). Arrows
indicate dying cells, which showed increased Bad immunoreactivity.
Scale bar, 20 µm. D, TUNEL staining. The number of
TUNEL-positive cells was counted in four different fields with a size
of 326 × 326 µm in the ipsilateral side of each animal. Three
mice were used in each group. A high number of TUNEL-positive cells was
detected 1 d after tMCAO in the striatum of lacZ-transduced mice
(a). These TUNEL-positive cells showed apoptotic
features, including shrunken cell bodies and condensed nuclei, as
indicated by arrows. The number of TUNEL-positive cells
was reduced in TGF-1-transduced mice (b).
Arrowheads indicate TUNEL-negative cells with normal
morphology. Scale bar, 20 µm. Quantitative analysis indicated a
significant reduction of the number of TUNEL-positive cells in the
ipsilateral side of TGF-1-transduced mice (c).
**p < 0.01, compared with lacZ control.
E, Double staining of P-Erk1/2 and neuronal marker NSE
(a-c) or astrocyte marker GFAP
(d-f) in the ischemic core of
TGF-1-transduced mice 48 hr after tMCAO. P-Erk1/2 (a,
c) was colabeled with NSE (b) and GFAP
(e). The overlap of P-Erk1/2-NSE and
P-Erk1/2-GFAP is shown in c and f,
respectively. Scale bar, 20 µm.
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To confirm the antiapoptotic effect of TGF-1 in vivo,
TUNEL staining was performed 1 d after tMCAO. A high number of
TUNEL-positive cells with shrunken nuclei and condensed chromatin, as
indicated by arrows, was detected in the lesioned striatum
of lacZ-injected control mice (Fig. 2D, a), whereas
the number of TUNEL-positive cells was much less in the striatum of
TGF-1-transduced mice (Fig. 2D, b). Quantitative
analysis revealed an ~50% reduction of the number of TUNEL-positive
cells in TGF-1-transduced brains (Fig. 2D, c).
We further tested whether inhibition of apoptotic cascades by TGF-1
contributed to neuroprotection and improvement of the neurological
outcome after ischemia. As shown in Figure
3A, the striatal region was
severely lesioned in saline and lacZ controls, but to a much less
extent in TGF-1-transduced mice. Quantitative analysis revealed that
the ischemic lesion in TGF-1-transduced mice was reduced by 40%
(p < 0.001) 1 d after tMCAO (Fig.
3B) in comparison with that in saline and lacZ controls.
Evaluation of neurological outcome by the beam test showed that
cerebral injection of either saline or AdRSVlacZ or AdRSVTGF-1 to
nonischemic mice did not cause any neurological deficiency. Thirty
minutes of cerebral ischemia markedly increased the number of falls
from the beam in mice subjected to either saline or AdRSVlacZ injection but to a lesser extent in TGF-1-transduced mice (Fig.
3C). The reduction of the ischemic lesion and the functional
improvement of neurological outcome indicated a neuroprotective potency
of TGF-1 in vivo.
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Figure 3.
Overexpression of TGF-1 reduces the ischemic
lesion and improves the neurological outcome of ischemic mice. The
brains were removed from the saline-treated and lacZ- and
TGF-1-transduced mice. The cryostat sections were cut continuously
and stained with cresyl violet. A, Photographs of the
ischemic lesion 1 d after tMCAO. B, Quantitative
analysis of the ischemic lesion 1 d after tMCAO. Data are
expressed as means ± SD of 10 animals for each group. There was
no difference between saline-treated and lacZ-transduced mice.
***p < 0.001 compared with lacZ-transduced mice.
C, Improvement of the neurological outcome in
TGF-1-transduced mice after ischemia. The neurological deficiency
was evaluated by a beam test before cerebral injection on the fifth day
after cerebral injection without ischemia and 1 d after tMCAO.
Intracerebral injection did not cause neurological deficiency in
nonischemic mice (shaded columns) of all three groups in
comparison with those before injection (open columns).
Thirty minutes of MCAO led to a severe neurological deficiency in
saline-treated or lacZ-transduced mice at 1 d after ischemia but
to a lesser extent in TGF-1-transduced mice as evidenced by the
significant decrease in the falls from the beam (on the sixth day after
cerebral injection; filled columns). Data are expressed
as means ± SD of 13-20 animals for each group. There was no
difference between saline-treated and lacZ-transduced mice.
*p < 0.05 compared with lacZ-transduced
mice.
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Overexpression of TGF-1 increased phosphorylation of Erk1/2,
Rsk1, and Bad in the striatum of nonischemic mice
To investigate whether TGF-1 transduction was
able to activate the MAPK cascade and to phosphorylate Bad, the levels
of P-Erk1/2, phospho-Rsk1 (P-Rsk1), and
phospho-Ser112-Bad (P-Bad) were detected
by Western blot analysis of striatal tissue, the most vulnerable region
to tMCAO. As shown in Figure 4A, the levels of
P-Erk1/2 and P-Rsk1 increased in a time-dependent manner after TGF-1
transduction. The P-Bad level was enhanced concomitantly in the
striatum of TGF-1-transduced mice. Semiquantification of the blots
revealed an approximately threefold increase in the levels of P-Erk1,
P-Rsk1, and P-Bad from days 7 to 14 after TGF-1 transduction in
comparison with the lacZ control (Fig. 4B). The level
of Bad protein in these nonischemic mouse brains was not changed at any
detected time point after adenoviral transduction. The results suggest
a correlation between activation of MAPK signaling and phosphorylation
of Bad at Ser112 mediated by TGF-1.
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Figure 4.
Adenovirus-mediated TGF-1 overexpression
activates Erk1/2 and Rsk1 and increases phosphorylation of Bad in the
striatum of nonischemic mice. A, Representative blots
for P-Erk1/2, P-Rsk1
(Thr360/Ser364), P-Bad
(Ser112), Bad, and -tubulin. Mice were subjected
to intracerebral injection of either AdRSVlacZ or AdRSVahTGF-1. The
striatum tissues were isolated, and proteins were extracted at
different time points after injection. Sixty micrograms of total
protein were loaded to each lane for Western blot. Blots were
representative of three animals at each time point. B.
Semiquantification of blots. The ratio of the IOD of P-Erk1, 2, P-Rsk1,
P-Bad, and Bad signals to -tubulin signals was calculated. The
ratios obtained from LacZ-injected mice were normalized to 100%, and
the data were given as means ± SD of the percentage of
lacZ-transduced controls. *p < 0.05;
**p < 0.01; ***p < 0.001 compared with lacZ-transduced mice.
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The levels of P-Erk1/2 were also immunohistochemically studied 5 d
after either lacZ or TGF-1 transduction in mouse brain. The negative
control did not show detectable immunofluorescence (Fig. 1C,
a). Immunoreactivity of P-Erk1/2 was weakly detected in the
cytoplasma of neurons in cortex (Fig. 1C, b) and striatum (Fig. 1C, d) of lacZ-transduced mice, whereas enhanced
P-Erk1/2 expression was observed in both the extracellular space and
the cytoplasma of cortical (Fig. 1C, c) and striatal (Fig.
1C, e) neurons in TGF-1-transduced mice. It was of note
that P-Erk1/2 was also highly expressed in the region surrounding
vessels, similar to that observed in TGF-1 immunostaining (Fig.
1B, c, e), indicating a concomitant increase in
TGF-1 expression and activation of Erk1/2.
Overexpression of TGF-1 increased phosphorylation of Erk1/2,
Rsk1, and Bad, and suppressed expression of death protein Bad as well
as caspase-3 activation in brain tissue after tMCAO
Next, we investigated how TGF-1 transduction in mouse brain
influenced the activation of MAPK cascades after cerebral ischemia. The
level of P-Erk1/2 moderately increased 8 and 24 hr after and was
markedly enhanced (12- and 16-fold increases in P-Erk1 and P-Erk2,
respectively) 48 hr after tMCAO in the striatum of lacZ-transduced mice
in comparison with lacZ-injected, sham-operated mice (Fig. 5A, first panel, B).
Phosphorylation of Rsk1, a downstream kinase of Erk1/2, increased
moderately in lacZ-transduced mice after tMCAO (Fig. 5A, second
panel, B), whereas the level of P-Bad was slightly elevated (Fig.
5A, third panel, B). Notably, ischemia led to a 30-fold
increase in Bad expression 8 hr after reperfusion (Fig. 5A,
fourth panel, B), accompanied by a fivefold activation of
caspase-3 (Fig. 5A, fifth panel, B). TGF-1 transduction
resulted in 4- and 15-fold increases in P-Erk1 and P-Erk2 levels,
respectively, at 8 hr after tMCAO, and they further increased 24 hr
after tMCAO compared with the lacZ controls (Fig. 5A, first
panel, B). A 3.5-fold increase in the P-Rsk1 level was observed in
TGF-1-transducd mice at 8 hr after tMCAO compared with
lacZ-transduced controls (Fig. 5A, second panel, B), whereas
P-Bad was increased approximately fourfold (Fig. 5A, third panel,
B). P-Bad was maintained at this level up to 24 hr in
TGF-1-transduced brain after ischemia and then declined 48 hr after
tMCAO, but it was still twofold higher than in lacZ-transduced
controls. Overexpression of TGF-1 significantly reduced the level of
Bad protein (Fig. 5A, fourth panel, B) and the activation of
caspase-3 8 hr after ischemia. The latter was no longer detectable in
TGF-1-transduced mice 24 and 48 hr after tMCAO (Fig. 5A, fifth
panel, B). These results were consistent with the findings
revealed by immunostaining of Bad and active caspase-3 (Fig.
2A).
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Figure 5.
Adenovirus-mediated TGF-1 overexpression
activates Erk1/2 and Rsk1 and interrupts apoptotic cascades through
modulation of Bad expression and inhibition of caspase-3 activation in
ischemic mice. A, Representative blots of P-Erk1/2,
P-Rsk1 (Thr360/Ser364), P-Bad
(Ser112), Bad, caspase-3, and -tubulin. The mice
were subjected to intracerebral injection of either AdRSVlacZ or
AdRSVahTGF-1. Thirty minutes of MCAO or sham operation was performed
on the fifth day after the injection. The striatal tissues were
isolated, and proteins were extracted at the defined time points after
ischemia. Sixty micrograms of total protein were loaded to each lane
for Western blot. Blots were representative for three animals for each
time point. B, Semiquantification of blots. The ratio of
IOD from P-Erk1/2, P-Rsk1, P-Bad, Bad, and caspase-3 signals to
-tubulin signals was calculated. The ratios obtained from
sham-operated mice were normalized to 100%, and the data were given as
means ± SD of the percentage of controls. Caspase-3 activation
was not detectable in TGF-1-transduced mice at 24 and 48 hr after
tMCAO. *p < 0.05; **p < 0.01; ***p < 0.001 compared with sham-operated
mice.
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To further identify the cell phenotypes that accounted for the
persistent elevation of the P-Erk1/2 level in the TGF-1-transduced brains at the late stage of reperfusion, double staining of
P-Erk1/2-NSE and P-Erk1/2-GFAP was performed on the brain sections
prepared 48 hr after tMCAO. As shown in Figure 2E,
P-Erk1/2 (Fig. 2E, a, d) was colabeled with the
neuronal marker NSE (Fig. 2E, b, c) as well as with
the astrocyte marker GFAP (Fig. 2E, e, f),
indicating that both neurons and astrocytes were involved in the
expression of P-Erk1/2.
TGF-1 activated Erk1/2 and Rsk1 and enhanced phosphorylation of
Bad in cultured hippocampal cells, which was blocked by U0126
The effect of TGF-1 on activation of MAPK cascades and on
phosphorylation of Bad was further characterized in neuronal cultures. Cultured rat hippocampal cells were treated with different
concentrations of TGF-1, and cells were harvested at different time
points after the onset of the treatment. As shown in Figure
6A, the levels of
P-Erk1/2, P-Rsk1, and P-Bad concomitantly increased in a
concentration-dependent manner. Notably, TGF-1 (10 ng/ml) caused a
fivefold increase in the level of P-Bad, as revealed by
semiquantitative analysis of the blots (Fig. 6B).
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Figure 6.
TGF-1 concentration-dependently activates
Erk1/2 and Rsk1 and increases phosphorylation of Bad in cultured rat
hippocampal cells. A, Representative blots of P-Erk1/2,
P-Rsk1 (Thr360/Ser364), P-Bad
(Ser112), Bad, and -tubulin. TGF-1 (0.1, 1.0, and 10 ng/ml) was administered to the hippocampal cells on the seventh
day of culture. Controls received vehicle only. The cells were
harvested in a lysis buffer 8 hr after adding TGF-1 or vehicle.
Thirty micrograms of total protein from each group were loaded to
SDS-polyacrylamide gel. Blots were representative of three independent
experiments. B, Semiquantification of the blots. We
calculated the ratio of IOD from the signals of P-Erk1/2, P-Rsk1, and
P-Bad to -tubulin, and the ratios obtained from vehicle-treated
controls (0 ng/ml) were normalized to 100%. The data were given as
means ± SD of the percentage of controls. *p < 0.05; ***p < 0.001 compared with vehicle
treated-control.
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Activation of Erk1/2 and Rsk1 as well as an increase in Bad
phosphorylation were detected in cultured hippocampal cells as early as
15 min after adding 10 ng/ml TGF-1 (Fig.
7A). The levels of P-Erk1/2,
P-Rsk1, and P-Bad were continuously elevated 1 and 8 hr after the onset
of TGF-1 treatment. The semiquantitative analysis of the blots
indicated a fivefold increase in P-Bad level 8 hr after the onset of
TGF-1 treatment. They declined 24 hr after the administration of
TGF-1 but were still higher than those detected in the controls
(Fig. 7B). To get evidence that activation of MAPK by
TGF-1 mediated the increase in Bad phosphorylation, U0126, a
specific MEK and Erk1/2 inhibitor, was added to the cells 2 hr before
the exposure of TGF-1. U0126 completely blocked the phosphorylation
of Erk1/2, Rsk1, and Bad, suggesting that TGF-1-mediated phosphorylation of Bad is mediated by the MAPK/Erk1/2 cascade (Fig.
7A).
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Figure 7.
Time course of activation of Erk1/2 and Rsk1 as
well as phosphorylation of Bad after administration of TGF-1 in the
cultured rat hippocampal cells. A, B, Representative
blots of P-Erk1/2, P-Rsk1
(Thr360/Ser364), P-Bad
(Ser112), Bad and -tubulin and the
semiquantification of the blots. TGF-1 (10 ng/ml) was added to the
hippocampal cells on the seventh day of culture. To block MAPK
signaling, U0126 (20 µM) was added 2 hr before the
exposure of TGF-1. Controls received vehicle only. The cells were
harvested in a lysis buffer at 15 and 30 min (A)
as well as 1, 8, and 24 hr (B) after adding
TGF-1. Thirty micrograms of total protein from each group were
loaded to SDS-polyacrylamide gel. Blots were representative of three
independent cultures. The ratio of IOD from P-Erk1/2, P-Rsk1, and P-Bad
signals to -tubulin signals was calculated. The ratios obtained from
vehicle-treated controls (either 30 min or 24 hr) were normalized to
100%, and the data were given as means ± SD of the percentage of
the corresponding control. *p < 0.05;
**p < 0.01; ***p < 0.001, compared with vehicle-treated control (30 min);
#p < 0.05;
##p < 0.01;
###p < 0.001 compared with
vehicle-treated control (24 hr).
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TGF-1 suppressed the level of Bad protein in
staurosporine-treated hippocampal cells
To confirm the inhibitory effect of TGF-1 on the lesion-induced
increase in Bad protein expression, we detected Bad protein expression
in staurosporine-treated hippocampal cells in the presence and absence
of TGF-1. The level of Bad protein increased 1.8- and 1.6-fold 6 and
24 hr after the exposure to staurosporine, respectively, compared with
the corresponding vehicle-treated controls. TGF-1 at the
concentration of 1 ng/ml effectively diminished the elevation of Bad
protein level caused by staurosporine, whereas 10 ng/ml TGF-1
further reduced Bad expression by 50 and 30% at 6 and 24 hr,
respectively, after the treatment of staurosporine in comparison with
controls (Fig. 8C,D). However,
TGF-1 did not influence Bad protein levels in the absence of
staurosporine (Fig. 8A,B).
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Figure 8.
TGF-1 suppresses the increase in Bad protein
level in cultured rat hippocampal cells induced by staurosporine.
A, Representative blots of Bad and -tubulin 6 and 24 hr after the treatment of TGF-1 (10 ng/ml) in the absence of
staurosporine. B, Semiquantification of the blots
presented in A. The ratio of IOD from Bad signals to
-tubulin signals was calculated. The ratios obtained from
vehicle-treated controls (either 6 or 24 hr) were normalized to 100%,
and the data were given as means ± SD of the percentage of
controls. C, Representative blots of Bad and -tubulin
in the presence of staurosporine. TGF-1 (1 and 10 ng/ml) was added
to the hippocampal cells 24 hr before the onset of staurosporine
(Stau, 100 nM) treatment. Cells were
harvested at 6 and 24 hr after the exposure to staurosporine. Controls
received vehicle only. Blots were representative for three independent
experiments. D, Semiquantification of the blots
presented in C. *p < 0.05 compared
with the vehicle-control; #p < 0.05 compared with staurosporine-treated cells.
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U0126 and Ro318220 abolished the TGF-1-mediated increase in
phosphorylation of Bad and the antiapoptotic effect of TGF-1 in
cultured hippocampal cells
To clarify whether the antiapoptotic effect of TGF-1 was
mediated by activation of MAPK signaling, U0126 and Ro318220 were added
to cells 2 hr before the exposure of TGF-1 (10 ng/ml). Apoptosis was
induced by 100 nM staurosporine, which was given to the
cells 24 hr after the onset of TGF-1 treatment. As revealed by
nuclear staining with Hoechst 33258, TGF-1 significantly reduced the
percentage of apoptotic neurons, which was in agreement with our
previous report (Zhu et al., 2001). This effect was completely abolished by U0126 (20 µM) (Fig.
9A) and Ro318220 (5 µM) (Fig. 9C). U0126 at the
concentration of 10 µM only partially blocked the neuroprotection by TGF-1, and Ro318220 at the concentration of
10 µM was toxic (data not shown).
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Figure 9.
MEK/Erk1/2 and Rsk inhibitors block the
antiapoptotic effect of TGF-1 and inhibit TGF-1-mediated
phosphorylation of Erk1/2, Rsk1 and Bad in cultured rat hippocampal
cells. TGF-1 (10 ng/ml) was administered to the hippocampal cells on
the seventh day of culture. Staurosporine (Stau, 100 nM) was added to the medium 24 hr after onset of TGF-1
treatment. To block the activation of MEK/Erk1/2 or Rsk1, U0126 (20 µM) or Ro318220 (5 µM) was added to the
cells 2 hr before exposure of TGF-1, respectively. Controls received
vehicle only. A, C, U0126 and Ro318220 abolished the
antiapoptotic effect of TGF-1. The nuclear morphology was analyzed
under a fluorescence microscope after nuclear staining with Hoechst
33258. The cells showing condensed chromatin, and fragmented nuclei
were counted as apoptotic cells. The data are expressed as the
percentage of means ± SD ###p < 0.001 compared with vehicle-treated control; **p < 0.01; ***p < 0.001 compared with cultures treated
with staurosporine alone; ++p < 0.01;
+++p < 0.001, compared with cultures
treated with staurosporine plus TGF-1. The experiments were
representative of three independent cultures. B, D,
TGF-1-mediated activation of Erk1/2, Rsk1 and increase in
phosphorylation of Bad were inhibited by U0126
(B) and Ro318220 (D). The
cells were harvested in lysis buffer 24 hr after adding staurosporine.
Thirty micrograms of total protein from each group were loaded to
SDS-polyacrylamide gels, and P-Erk1/2, P-Rsk1
(Thr360/Ser364) and P-Bad
(Ser112) proteins were analyzed using specific
antibodies. -Tubulin blots were used for controlling the amount of
protein loaded in each lane. The experiments were representative of
three independent experiments.
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Using the same treatment protocol, it was further demonstrated that
U0126 completely blocked the basal phosphorylation of Erk1/2 and
suppressed the basal phosphorylation of Rsk1 and Bad under control
conditions. The latter implies that Erk1/2 is not the sole kinase for
activation of Rsk1. Staurosporine alone did not affect the level of
P-Erk1/2 and P-Rsk1, supporting the finding that Erk was a
staurosporine-insensitive kinase (McCubrey et al., 2000). However,
increased phosphorylation of Erk1/2, Rsk1, and Bad was clearly detected
when TGF-1 was added to the cells 24 hr before the exposure of
staurosporine, and this increase was no longer seen in the presence of
U0126 (Fig. 9B). To support these findings, another MAPK
pathway inhibitor, Ro318220, was used. Ro318220 nearly abolished both
the basal and TGF-1-mediated phosphorylation of Rsk1, whereas the
phosphorylation of Erk1/2 was not influenced, suggesting that Rsk1
acted downstream of Erk1/2. Importantly, Ro318220 markedly suppressed
the basal level of P-Bad as well as the TGF-1-mediated increase in
Bad phosphorylation, indicating the requirement of Rsk1 activation for
the phosphorylation of Bad (Fig. 9D).
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DISCUSSION |
Most cells, including those in the CNS, are capable of expressing
TGF-1 and TGF- receptors. Accordingly, the spectrum of cellular
activities of TGF-1 is extremely diverse (Unsicker and Strelau,
2000). The role of TGF-1 in apoptosis varies depending on the cell
type and their developmental stage as well as on the specific stimulus
(De Luca et al., 1996; Krieglstein and Krieglstein, 1997; Krieglstein
et al., 2000). Indeed, little is known about the signal transduction
pathways mediating its role in apoptosis. In the present study we
demonstrated the following: (1) Adenovirus-mediated overexpression of
TGF-1 in mouse brain interfered with the apoptotic process after
tMCAO through suppressing Bad protein expression, increasing Bad
phosphorylation, and inhibiting caspase-3 activation. Consequently,
ischemia-induced DNA degradation and cerebral lesions were decreased,
and the neurological outcome was improved in TGF-1-transduced mice.
The inhibitory effect of TGF-1 on Bad expression was also found in
staurosporine-treated hippocampal cells. (2) TGF-1 was able to
activate the MAPK/Erk1/2 pathway under nonischemic and ischemic
conditions, which was concomitantly related to an increase in
phosphorylation of Bad in mouse brain. Similarly, TGF-1 activated MAPK/Erk1/2 signaling and increased phosphorylation of Bad in a
concentration- and time-dependent manner in cultured rat hippocampal cells. Both events were completely blocked by U0126, suggesting a link
between MAPK/Erk1/2 and phosphorylation of Bad caused by TGF-1. (3)
TGF-1 protected cultured rat hippocampal cells from staurosporine-induced apoptosis, and this effect was abolished by
either U0126 or Ro318220, indicating a requirement of Erk1/2 and Rsk1
activation for the antiapoptotic activity of TGF-1.
We used adenovirus-mediated TGF-1-transduced mice in the
present study because this model has advantages for studying the role of TGF-1 in vivo. First, a desired TGF-1 level
(1-1.5 ng/gm of brain tissue), which was almost the same as the
neuroprotective concentration of TGF-1 identified in our previous
study (Henrich-Noack et al., 1996), was achieved in brain tissue from
the 5th to 10th day after a single injection of AdRSVahTGF-1 (Fig.
1) without an influence of the level of TGF-1 in the blood
plasma. This is usually difficult to achieve by the single or multiple
intracerebral injection of exogenous TGF-1 because of its short
half-life (Wakefield et al., 1990). Second, adenovirus transduction of
TGF-1 did not influence the cerebral blood flow; thus we can exclude
the possibility that an increase in cerebral blood flow contributed to
the neuroprotective effect of TGF-1.
Bcl-2 and caspase family proteins are known to play a central role in
the regulation of apoptosis. Activation of caspase-3, a critical member
of the caspase family, accelerates apoptosis and thus has been
suggested as an apoptotic marker (Chen et al., 1998; Lee et al., 1999;
Schulz et al., 1999). Bad is a Bcl-2 homology domain-only
proapoptotic member of the Bcl-2 family, and a massive increase in Bad
expression has been found to kill cells. Furthermore, dephosphorylated
Bad forms a complex with the antiapoptotic proteins Bcl-xl or Bcl-2,
thereby displacing the apoptotic promoter Bax. Phosphorylated Bad can
dissociate from this complex, which in turn results in the liberation
of Bcl-xl and Bcl-2 (Hsu et al., 1997; Scheid et al., 1999). Thus,
phosphorylation of Bad has been suggested to be essential for
inactivation of its proapoptotic activity (Lizcano et al., 2000; Virdee
et al., 2000; Zhou et al., 2000; Dramsi et al., 2002). Phosphorylation
of Bad at Ser112 in response to MAPK
activation was absolutely required for dissociation of Bad from Bcl-xl
(Bonni et al., 1999; Fang et al., 1999; Scheid et al., 1999). In light
of these findings, we propose that modulation of Bad expression by
TGF-1 would interfere with the apoptotic cascade in the CNS. Here we
provide evidence that TGF-1 increased Bad phosphorylation at
Ser112 in striatal tissue under both
nonischemic and ischemic conditions, as well as in cultured hippocampal
cells in the presence or absence of apoptotic stimuli. This event is
tightly associated with activation of the MAPK/Erk1/2 pathway. In
addition, overexpression of TGF-1 inhibited Bad expression, which
had been dramatically increased after tMCAO. These effects may
crucially contribute to the antiapoptotic effect of TGF-1, i.e.,
inhibition of caspase-3 activation, prevention of DNA fragmentation,
reduction of ischemic lesion, and the final improvement of neurological
function after cerebral ischemia. Interestingly, the inhibitory effect
of TGF-1 on Bad expression was observed only under damaging
conditions in both in vivo and in vitro
experiments. Most likely, TGF-1 interferes with a mechanism that
upregulates Bad in apoptosis and that is yet to be defined.
An important link between kinase signaling pathways and the cellular
apoptotic machinery has been established after the discovery that Bad
is phosphorylated in response to activation of MEK/Erk1/2, phosphatidylinositol 3-kinase/Akt, and cAMP-dependent protein kinase. In particular, MAPK/Erk1/2 has been suggested to be important for intracellular signaling mediating cell survival-promoting effects
of growth factors such as glial cell line-derived neurotrophic factor
(Nicole et al., 2001), BDNF (Hetman et al., 1999; Han and Holtzman,
2000), basic fibroblast growth factor (Gardner and Johnson, 1996; Abe
et al., 2001), EGF (Gleichmann et al., 2000), and insulin-like growth
factor-1 (Parrizas et al., 1997) and the cytokine IL-3 (Shimamura et
al., 2000). More recently, evidence for either positive (Reimann et
al., 1997; Chin et al., 1999; Chio, 2000; Lhuillier and Dryer,
2000; Mulder, 2000) or negative (Chang, 2000) regulatory effects of
TGF-1 on MAPK activation has been shown, depending on the cell type
and experimental conditions. However, little is known about the role of
TGF-1 in MAPK activation in the nervous system, and to our
knowledge, data dealing with TGF-1-mediated MAPK activation and Bad
phosphorylation are not yet available. In this study, we demonstrated
that TGF-1 concomitantly increased phosphorylation of Erk1/2,
Rsk1, and Bad (Ser112) both in mouse brain
and in cultured rat hippocampal cells. Blocking of Bad phosphorylation
by the MEK/Erk1/2 inhibitor U0126 in cultured rat hippocampal cells
indicated that the MAPK pathway was required for the phosphorylation of
Bad at Ser112.
The MAPK/Erk signaling pathway has been intensively studied in
different types of cultured cells, including cultured neurons (Anderson
and Tolkovsky, 1999; Hetman et al., 1999; Abe et al., 2001;
Chang and Karin, 2001). However, its role in the brain and in setting
CNS disease is not clear. The activation of MAPK/Erk signaling in
neurons plays a central role in controlling synaptic plasticity and
memory (Sweatt, 2001) and is implicated in the pathological processes
after cerebral ischemia (Sugino et al., 2000; Wu et al., 2000).
Alessandrini et al. (1999) reported a reduction of brain damage by the
MEK1 inhibitor PD98059 after focal cerebral ischemia. The same
group also recently showed the neuroprotective effect of the MEK/Erk1/2
inhibitor U0126 after either global or focal cerebral ischemia (Namura
et al., 2001). However, others found that MAPK/Erk1/2 inhibitors did
not reduce brain damage after global ischemia (Sugino et al., 2000) or
after hypoxia (Han and Holtzman, 2000). Furthermore, it has been
documented that activation of MAPK/Erk1/2 was involved in the
mechanisms of ischemic tolerance (Gonzalez-Zulueta et al., 2000) and
mediated the neuroprotective effect of BDNF after either
hypoxic-ischemic injury in neonatal rats (Han and Holtzman, 2000) or
traumatic CNS injury in adult rats (Klöcker et al., 2000). In
this study, we showed that activation of MAPK/Erk1/2 signaling was
consistently accompanied by an increase in Bad phosphorylation in
either nonischemic or ischemic mouse brain after adenovirus-mediated
TGF-1 transduction. Moreover, overexpression of TGF-1 in mouse
brain resulted in a neuroprotective effect after tMCAO, as evidenced by
attenuation of DNA degradation, reduction of the brain infarction, and
improvement of the neurological outcome, in which MAPK/Erk1/2 was
consistently activated. These findings suggest a beneficial
contribution of the MAPK pathway to the neuroprotection by
TGF-1. To support this hypothesis, we showed that U0126 and Ro318220
completely abolished the protective effect of TGF-1 in cultured
hippocampal cells, indicating that activation of Erk1/2-Rsk1 signaling
was necessary for the antiapoptotic effect of TGF-1. Consistent with the blockade of the antiapoptotic activity of TGF-1, the
phosphorylation of Erk1/2, Rsk1, and Bad mediated by TGF-1 was
diminished by both MAPK inhibitors. These results obtained
from the in vitro experiments could to some extent support
our findings observed in ischemic brain tissue. However, it is realized
that staurosporine-induced apoptosis may have less ischemic relevance,
although it is a widely used model for study of apoptosis. Therefore,
it is worthwhile to confirm these findings using a more ischemic
relevant in vitro model, for instance, hypoxia. Furthermore,
application of an MAPK/Erk1/2 inhibitor in vivo would
directly reveal the role of MAPK activation in the neuroprotective
effect of TGF-1 after cerebral ischemia.
The major findings of the present study are schematically summarized in
Figure 10. Considering the importance
of sustaining survival signaling and, in addition, suppressing death
promoters in the injured brain, we suggest that the inhibition of Bad
protein expression under lesion conditions and the increase in Bad
phosphorylation through the MAPK/Erk1/2 pathway by TGF-1 may
represent a pivotal step in the neuroprotective effect of this
cytokine.
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Figure 10.
Scheme summarizing the major findings of this
study. Either adenovirus-mediated overexpression of TGF-1 in mouse
brain or administration of TGF-1 to the cultured hippocampal cells
caused an activation of Erk1/2 and Rsk1, consistently accompanied by an
increase in phosphorylation of Bad (Ser112).
TGF-1-mediated activation of MAPK, phosphorylation of Bad, and an
antiapoptotic effect in cultured hippocampal cells were abolished by
MEK/Erk1/2 and Rsk1 inhibitors, indicating a tight association between
MAPK activation and Bad phosphorylation, as well as a requirement of
MAPK pathway for the antiapoptotic activity of TGF-1. It is proposed
that the increase in phosphorylation of Bad may lead to a dissociation
of Bcl-2 and Bcl-xl from the complex of Bad/Bcl-xl or Bad/Bcl-2, which
in turn interrupts multiple apoptotic cascades, including inhibition of
caspase-3 activation. These effects, together with the inhibitory
effect of TGF-1 on the lesion-mediated increase in Bad level, may
crucially contribute to the neuroprotective activity of TGF-1, as
evidenced by decrease in DNA degradation and ischemic lesions, as well
as the improvement of the neurological outcome after cerebral
ischemia.
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FOOTNOTES |
Received Sept. 4, 2001; revised Jan. 28, 2002; accepted Feb. 8, 2002.
This study was supported by Deutsche Forschungsgemeinschaft Grant Kr
359/16-3,4 and National Institutes of Health Grant R01 NS-35089. We
thank Michaela Stumpf and Sandra Engel for skillful technical assistance.
Correspondence should be addressed to Dr. Yuan Zhu, In
TOP
ABSTRACT
INTRODUCTION
