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The Journal of Neuroscience, July 1, 2002, 22(13):5423-5431
In Vivo Delivery of a Bcl-xL Fusion Protein
Containing the TAT Protein Transduction Domain Protects against
Ischemic Brain Injury and Neuronal Apoptosis
Guodong
Cao1, 2,
Wei
Pei1, 2,
Hailiang
Ge1, 2,
Qinhua
Liang1, 2,
Yumin
Luo1, 2,
Frank R.
Sharp3,
Aigang
Lu3,
Ruiqiong
Ran3,
Steven H.
Graham1, 2, 4, and
Jun
Chen1, 2, 4
1 Department of Neurology and 2 Pittsburgh
Institute for Neurodegenerative Disorders, University of Pittsburgh
School of Medicine, Pittsburgh, Pennsylvania 15261, 3 Department of Neurology, University of Cincinnati Medical
College, Cincinnati, Ohio 45267, and 4 Geriatric Research,
Educational and Clinical Center, Veterans Affairs Pittsburgh Health
Care System, Pittsburgh, Pennsylvania 15261
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ABSTRACT |
Bcl-xL is a well characterized death-suppressing molecule of the
Bcl-2 family. Bcl-xL is expressed in embryonic and adult neurons of the
CNS and may play a critical role in preventing neuronal apoptosis that
occurs during brain development or results from diverse pathologic
stimuli, including cerebral ischemia. In this study, we used a novel
approach to study the potential neuroprotective effect of Bcl-xL as a
therapeutic agent in the murine model of focal ischemia/reperfusion. We
created a Bcl-xL fusion protein, designated as PTD-HA-Bcl-xL, which
contains the protein transduction domain (PTD) derived from the
human immunodeficiency TAT protein. We demonstrated that this fusion
protein is highly efficient in transducing into primary neurons in
cultures and potently inhibited staurosporin-induced neuronal
apoptosis. Furthermore, intraperitoneal injection of PTD-HA-Bcl-xL into
mice resulted in robust protein transduction in neurons in various
brain regions within 1-2 hr, and decreased cerebral infarction (up to
~40%) in a dose-dependent manner, as determined at 3 d after 90 min of focal ischemia. PTD-HA-Bcl-xL was effective even when it was administered after the completion of ischemia (up to 45 min), and the
protective effect was independent of the changes in cerebral blood flow
or other physiological parameters. Finally, as shown by
immunohistochemistry, Western blotting, and substrate-cleavage assays,
PTD-HA-Bcl-xL attenuated ischemia-induced caspase-3 activation in
ischemic neurons. These results thus confirm the neuroprotective effect
of Bcl-xL against ischemic brain injury and provide the first evidence
that the PTD can be used to efficiently transduce a biologically active
neuroprotectant in experimental cerebral ischemia.
Key words:
cerebral ischemia; stroke; protein transduction; Bcl-2; caspase-3, cytochrome c
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INTRODUCTION |
Emerging evidence has suggested that
a significant portion of neuronal death after cerebral ischemia is
attributable to an active type of cell death reminiscent of apoptosis,
in which a number of apoptosis-regulatory gene products are activated
(Lipton, 1999 ; Schulz et al., 1999; Sharp et al., 2000; Graham and
Chen, 2001). Of the prime gene products involved in ischemic neuronal death, the Bcl-2 family proteins may play a critical role (Graham et
al., 2000; Graham and Chen, 2001). Although the pro-apoptotic proteins
such as Bax and Bid promote cell death after ischemia (Chen and Yin,
2000; Plesnila et al., 2001), the anti-apoptotic proteins Bcl-2 and
Bcl-xL may enhance cell survival. Several studies demonstrated that
enhanced expression of Bcl-2 or Bcl-xL in rodent brain was associated
with markedly increased resistance to ischemic injury (Martinou et al.,
1994; Linnik et al., 1995; Lawrence et al., 1996, 1997; Parsadanian et
al., 1998; Wiessner et al., 1999). These observations strongly imply
that conditional augmentation of certain Bcl-2-like death-suppressing
proteins in the brain could be a clinically relevant strategy to
ameliorate ischemic brain injury.
Bcl-xL is a well characterized anti-apoptotic member of the Bcl-2
family, which is expressed in embryonic and adult neurons of the CNS
and plays an essential role in preventing neuronal cell death
(Gonzalez-Garcia et al., 1995; Motoyama et al., 1995; Blomer et al.,
1998; Parsadanian et al., 1998). In a manner similar to that of Bcl-2,
overexpression of Bcl-xL potently suppresses apoptotic cell death
induced by diverse stimuli in neurons and many other cell types
(Frankowski et al., 1995; Gonzalez-Garcia et al., 1995; Kharbanda et
al., 1997; Sastry and Rao, 2000; Shinoura et al., 2000) and, to a
lesser extent, suppresses hypoxia-induced necrosis (Tsujimoto et al.,
1997). Bcl-xL is an integral membrane protein localized primarily in
the mitochondrial membrane and the nuclear envelope (Tsujimoto and
Shimizu, 2000), and it suppresses cell death presumably by preventing
the release of apoptogenic factors from the mitochondria (Kluck et al.,
1997; Yang et al., 1997; Susin et al., 1999) and by directly
interacting with caspases (Hu et al., 1998; Pan et al., 1998). The
protein expression pattern of Bcl-xL has been studied previously in
rodent models of cerebral ischemia, and it was found that the
expression of Bcl-xL was dramatically decreased in dying ischemic
neurons but was retained in surviving neurons (Gillardon et al., 1996;
Isenmann et al., 1998; Kitagawa et al., 1998). Thus, Bcl-xL appears to
be a robust endogenous neuronal survival factor and an attractive
target for molecular therapeutic intervention in cerebral ischemia.
In this study, we generated a biologically active Bcl-xL fusion protein
containing the 11 aa protein transduction domain (PTD) derived from the
human immunodeficiency virus TAT protein (Nagahara et al., 1998).
Taking advantage of the powerful capability of the PTD fusion proteins
to transduce across the blood-brain barrier (Schwarze et al., 1999),
we studied the neuroprotective effect of Bcl-xL as a potential
therapeutic agent in a murine model of transient focal cerebral ischemia.
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MATERIALS AND METHODS |
Generation of Bcl-xL fusion protein containing the PTD
The cDNA encoding the entire reading frame of rat Bcl-xL was
isolated using PCR from a rat brain cDNA library (Chen et al., 1998).
PCR was performed using the primers
5'-ATGCGGCCGCGTCACTTCCGACTGAAGAGTGAG-3' (sense) and
5'-ACGATATCATGTCTCAGAGCAACCGGGAGCTG-3' (antisense). The products
generated by PCR were subcloned into the pSPORT1 vector (Invitrogen,
San Diego, CA), amplified, and purified, and the sequence was verified
by sequencing analysis (University of Pittsburgh Service Core Facility).
The ET-30 (a+) expression plasmid was reconstructed according to the
cloning sites provided by the manufacturer (Novagen, Madison, WI) to
allow the generation of hemagglutinin (HA)-tagged Bcl-xL fusion protein
that contains the PTD sequence. The final cDNA (which replaced the
enterokinase cloning site in the ET-30 plasmid) encodes peptide
sequences in the following order: his-6 tag (MHHHHHH), thrombin
cleavage site (SGLVPRGS), PTD (YGRKKRRQRRR), HA tag (YPYDVPDVA), and
Bcl-xL (233 aa), and the resulting vector is designated as
pET-PTD-HA-Bcl-xL. Two control plasmids were also constructed:
pET-PTD-HA-green fluorescent protein (GFP), in which
 -fetoprotein replaced Bcl-xL, and pET-HA-Bcl-xL, which contained the same sequences as pET-PTD-HA-Bcl-xL but without the PTD sequence.
To produce the fusion proteins, the plasmid was transformed into
Escherichia coli BL21 cells and protein expression was
induced using 0.5 mM
isopropylthiogalactoside at 37°C for 4 hr. The fusion proteins
were purified using an Ni-NTA superflow agarose column (Qiagen,
Hilden, Germany) according to the manufacturer's instructions. The
resulting fusion proteins were dialyzed twice against PBS using the 10K
Dialysis Cassette (Pierce, Rockford, IL) and then digested by thrombin
for 16 hr at room temperature to cleave the his-6 tag. This was
followed by secondary purification with the Ni-NTA superflow agarose
column to remove the his-6 tag and nonspecific binding proteins. The
purified proteins were verified by Coomassie blue staining and Western
blot analysis and were then stored in 10% glycerol/PBS at  80°C
until use.
Primary cortical neuronal culture and induction of apoptosis
Primary cultures of cortical neurons were prepared from 16- to
17-d-old Sprague Dawley rat embryos as described previously (Cao et
al., 2001b). Experiments were conducted at 14 d in
vitro, when cultures consisted primarily of neurons (~95%) as
determined using cell phenotype-specific immunocytochemistry (Cao et
al., 2001b).
Apoptosis was induced in cultured neurons by incubating the cells at
the indicated concentrations with staurosporin (STS) (Biomol, Plymouth
Meeting, PA). Apoptosis was evaluated 24 hr after STS incubation using
propidium iodide (PI) nuclear staining (Chen et al., 2000). The
percentage of cells showing apoptotic changes (chromatin condensation
and/or fragmentation) was quantified by counting  3000 cells under
each experimental condition (three randomly selected fields per well,
four to six wells per condition per experiment, and three independent
experiments). Cell viability was also measured in selective experiments
using the LIVE/DEAD viability/cytotoxicity kit (Molecular Probes,
Eugene, OR) according to the manufacturer's instructions.
Murine model of transient focal ischemia
Animal surgery. Focal cerebral ischemia was produced
by intraluminal occlusion of the left middle cerebral artery (MCA) with a nylon monofilament suture (Yang et al., 1994; Kondo et al., 1997).
Male 2- to 3-month-old C57BL/6 mice (25-30 gm each; The Jackson
Laboratory, Bar Harbor, ME) were anesthetized with 1.5% isoflurane in a 30% O2/70%
N2O mixture under spontaneous breathing. The
rectal temperature was controlled at 37.0 ± 0.5°C during
surgery and MCA occlusion via a temperature-regulated heating pad. Mean arterial blood pressure was monitored during MCA occlusion through a
tail cuff, and arterial blood gas was analyzed at 15 min after the
onset of ischemia. The animals underwent MCA occlusion for 90 min and
then reperfusion for  72 hr. After recovering from anesthesia, the
animals were maintained in an air-conditioned room at 20°C.
Measurement of cerebral blood flow. Changes in regional
cerebral blood flow before, during, and after MCA occlusion were
evaluated in animals using laser-Doppler flowmetry (Yang et al.,
1994).
Neurological deficits. At 24 hr after ischemia, neurological
examination was performed in surviving animals by an observer who was
blinded to the experimental conditions. Neurological deficits were
scored on the 0-5 scale (Murakami et al., 1998): 0, no neurological deficit; 1, failure to fully extend the right forepaw; 2, circling to
the right; 3, falling to the right; 4, unable to walk spontaneously; and 5, dead.
Determination of infarct volume. At 72 hr after MCA
occlusion, brains were removed and the forebrain was sliced into eight coronal sections (1 mm thick). Sections were stained with
2,3,5-triphenyltetrazolium (3%). Infarct volume was determined using
the microcomputer imaging device image analysis system (Imaging
Research Inc., St. Catharine's, Ontario, Canada) as described
previously (Chen et al., 1996). Animals that had a massive hematoma in
the brain or no infarction in the brain were omitted from additional
neurological and histological analysis.
In vivo administration of Bcl-x fusion proteins. To test the
therapeutic effect of PTD-HA-Bcl-xL against ischemic injury, the
purified fusion proteins at the indicated amounts were injected intraperitoneally at the indicated times into mice in 300 µl of PBS
and 10% glycerol. The animals received injection of PTD-HA-Bcl-xL or
control proteins (HA-Bcl-xL or PTD-HA-GFP) and were assigned randomly
to the experimental groups consisting of 8-12 animals each.
Western blot analysis and immunohistochemistry
Western blot analysis was performed using standard methods (Chen
et al., 1998). For immunohistochemistry, animals were anesthetized with
8% chloral hydrate and were then perfused with heparinized 0.9%
saline followed by 4% paraformaldehyde in 0.1 M phosphate buffer, pH 7.4. The brains were removed and postfixed in 30%
sucrosis/4% paraformaldehyde. Coronal sections 40 µM
thick were cut throughout the forebrain. For immunohistochemical
staining of HA (to detect the Bcl-xL fusion protein) or active
caspase-3, rabbit polyclonal antibodies were used at the dilution of
1:500 (anti-HA; Sigma, St. Louis, MO) and 1:100 (anti-active caspase-3;
Cell Signaling Technology, Inc., Beverly, MA), respectively. For
double-label immunofluorescence staining, sections were first incubated
with the rabbit anti-HA antibody at 4°C for 48 hr followed by
incubation for 2 hr at room temperature with goat anti-rabbit Cy3.18
immunoconjugate (Jackson ImmunoResearch, West Grove, PA) at 1:2500
dilutions. Sections were then subjected to incubation for 48 hr in
mouse anti-neuron-specific enolase (NSE) antibody (dilution at
1:200; Capricorn Products, Inc., Scarborough, ME), mouse
anti-neuronal-specific nuclear protein (NeuN) antibody (dilution
at 1:500; Chemicon, Temecula, CA), or mouse anti-glial fibrillary
acidic protein antibody (dilution at 1:200; Chemicon). This was
followed by incubation with biotin-conjugated anti-mouse antibody
(dilution at 1:3000) and then fluorescein-avidin D (Vector
Laboratories, Burlingame, CA) at 8 µg/ml. The sections were washed
four times in PBS, mounted in gelvatol, and coverslipped. For the
assessment of nonspecific staining, alternating sections from each
experimental condition were incubated without the primary antibody or
with the antibody that had been reabsorbed by excessive amounts of antigen.
Measurement of caspase-3-like protease activity
Caspase-3-like protease activity was measured in cell
extracts using the fluorogenic substrate
Ac-Acetyl-Asp-Glu-Val-Asp (DEVD) 7-amino-4-trifluoromethyl
coumarin (AFC) as described previously (Cao et al., 2001a). One
unit of the caspase-3-like activity corresponded to the caspase-like
activity that cleaves 1 pmol of AFC per minute at 37°C at
saturating substrate concentrations. To detect nonspecific protease
activity, in parallel experiments, the protein extracts were incubated
in the reaction buffer with a 5 µM
concentration of the caspase-3 inhibitor DEVD-aldehyde at room
temperature for 30 min before the addition of assay substrates, and the
values were subtracted from those obtained without the inhibitor.
Statistical analysis
Results are reported as mean values ± SEM. The
significance of differences between means was assessed by Student's
t test (single comparisons) or by ANOVA and post
hoc Scheffe's tests, with p < 0.05 considered
statistically significant.
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RESULTS |
Creation of a biologically active Bcl-xL fusion protein
To generate a Bcl-xL fusion protein containing the PTD (Fig.
1a), the full-length rat
Bcl-xL cDNA was isolated and subsequently subcloned into the ET-30 (a+)
plasmid that had been reconstructed to contain the sequences for two
tag peptides (his-6 and HA) and the PTD. Additional constructs lacking
either PTD (pET-HA-Bcl-xL) or Bcl-xL (PTD-HA-GFP) were also made.
The nucleotide sequences of all constructs were verified by sequencing
analysis before protein production. To prepare the Bcl-xL fusion
proteins for in vivo delivery, the proteins were expressed
in E. coli and subsequently purified to near
homogeneity, as shown by Coomassie blue staining (Fig. 1b).
The protein composition of these fusion proteins was further confirmed
using Western blot analysis with anti-HA or anti-Bcl-xL antibody (Fig.
1b).
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Figure 1.
The death-suppressing effect of PTD-HA-Bcl-xL in
primary cultures of cortical neurons. a, Structures of
the Bcl-xL fusion proteins. PTD-HA-Bcl-xL contains both HA tag and the
PTD, whereas HA-Bcl-xL does not contain the PTD; the latter served as
the control protein in subsequent studies. b,
Verification of the Bcl-xL fusion proteins. Coomassie blue
(CB) staining shows that the proteins have been
purified to near homogeneity. Western blots show that the proteins
could be detected using either anti-HA or anti-Bcl-x antibody.
c, Representative immunofluorescent images show the
transduction and death-suppressing effect in cortical neurons.
PTD-HA-Bcl-xL (B, low power; C, high
power) but not HA-Bcl-xL (A) transduces into
neurons within 15 min of exposure, as determined using HA
immunostaining. Immunofluorescence for HA (D) and
CCOX IV (E) are partially colocalized
(F, overlay), suggesting that a portion of the
transduced PTD-HA-Bcl-xL is associated with the mitochondria. The
addition of PTD-HA-Bcl-xL (H) but not
HA-Bcl-xL (I) reduces the amounts of
nuclei showing apoptotic changes (arrows), compared with
the vehicle control (G). Immunofluorescence for
cytochrome c is preserved in PTD-HA-Bcl-xL-treated
neurons (K) but not in HA-Bcl-xL-treated neurons
(L) or vehicle-treated neurons
(J), consistent with the speculation that
PTD-HA-Bcl-xL inhibits STS-induced cytochrome c release.
G-L were obtained 24 hr after STS. Scale bar, 20 µM. d, e, PTD-HA-Bcl-xL but not HA-Bcl-xL
or PTD-GFP inhibits STS-induced apoptosis in a dose-dependent manner
(d). PTD-HA-Bcl-xL was equally effective when it
was added to the cultures before or 1 hr after STS
(e). Apoptosis was quantified after PI staining
at 24 hr after STS exposure (0.3 µM). Data are mean ± SE from three independent experiments. **p < 0.01 versus vehicle controls (ANOVA and post hoc
Scheffe's tests). f, Western blots demonstrate that
PTD-HA-Bcl-xL treatment attenuated STS-induced cytochrome
c release to the cytoplasm in cultured neurons. Each
lane contains 20 µg of cytosolic protein, prepared
from noninduced (control) or STS-induced (0.3 µM for 6 hr) neurons, respectively. The blots are representative of three
independent experiments with similar results.
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The cellular-transduction and death-suppressing capabilities of Bcl-xL
fusion proteins were evaluated in the primary cultures of cortical
neurons. The addition of PTD-HA-Bcl-xL (1-10 µg/ml) but not
HA-Bcl-xL to the cultures resulted in rapid protein transduction into
nearly 100% of cells within 15 min of incubation, as shown by anti-HA
immunofluorescence (Fig. 1c, A-C). Transduction
of PTD-HA-Bcl-xL at the above concentrations did not show detectable cytotoxicity within 30 hr (measurement of lactate dehydrogenase release and Hoechst 33258 staining). Double-label immunofluorescence of
HA and cytochrome c oxidase (CCOX) IV showed
overlapping between these two antigens (Fig. 1c,
D-F). However, the PTD-HA-Bcl-xL immunofluorescence
showed a more diffusive intracellular pattern than cytochrome
c oxidase IV, suggesting that PTD-HA-Bcl-xL was distributed
in both mitochondria components and nonmitochondria components.
Cellular transduction of PTD-HA-Bcl-xL attenuated STS-induced apoptosis
in cortical neurons in a dose-dependent manner (Fig. 1d).
STS treatment at the concentration of 0.3 µM
triggered apoptosis in ~65% of neurons within 24 hr. When
PTD-HA-Bcl-xL was added 15 min before STS treatment, cell death was
markedly decreased, as determined using nuclear staining (Fig.
1d) or the LIVE/DEAD viability/cytotoxicity assay kit (data
not shown). In contrast, neither HA-Bcl-xL nor PTD-HA-GFP had a
protective effect at compatible concentrations. The concentrations of
PTD-HA-Bcl-xL that reached the half-maximal and maximal effect against
STS-induced apoptosis were ~1 µg/ml (33 nM)
and ~3 µg/ml (100 nM), respectively, whereas for the broad-spectrum caspase inhibitor
z-VAD-fmk to reach a similar protective effect,
concentrations of 30-100 µM were required (data not shown). These results indicated that PTD-HA-Bcl-xL is an
extremely potent anti-apoptotic agent. To determine the time window of
efficacy against STS neurotoxicity, PTD-HA-Bcl-xL was added to the
culture media at various time points before and after STS exposure. The
post-treatment of PTD-HA-Bcl-xL 1 hr after STS exposure was as
effective as most pretreatment regimens (Fig. 1e).
Because Bcl-xL is known to inhibit apoptosis by blocking cytochrome
c release, immunofluorescent staining for cytochrome
c was performed in cultures 24 hr after STS (0.3 µM) treatment without or with PTD-HA-Bcl-xL (3 µg/ml) treatment (Fig. 1c, J-L). PTD-HA-Bcl-xL significantly increased the percentages of neurons that retained cytochrome c immunofluorescence from 46.6 ± 3.8 to
84.1 ± 2.7% (p < 0.001). The effect of
PTD-HA-Bcl-xL on cytochrome c release was also confirmed by
Western blot analysis (Fig. 1f).
In vivo transduction of Bcl-xL fusion protein in
murine brain
The in vivo transduction capability of PTD-HA-Bcl-xL to
the brain was evaluated in adult male mice. Our preliminary studies suggested that PTD-HA-GFP could achieve robust transduction in the
brain 2-4 hr after systemic injection. Therefore, we initially performed Western blotting to detect PTD-HA-Bcl-xL in brain tissues at
4 hr after intraperitoneal injection of the protein. Marked dose-dependent increases in the amounts of PTD-HA-Bcl-xL protein were
detectable by either anti-HA or anti-Bcl-x antibody in various brain
regions, including the cortex (Fig.
2a), caudate-putamen, hippocampus, cerebellum, and spinal cord. In contrast, injection of
HA-Bcl-xL did not achieve detectable protein transduction. The
quantitative ELISA confirmed that the levels of Bcl-xL were increased
approximately twofold and sevenfold in the cortex after single
injections of PTD-HA-Bcl-xL at the doses of 3 and 9 mg/kg, respectively
(Fig. 2b). The time course for protein transduction of
PTD-HA-Bcl-xL in brain was also determined using ELISA after single
injections of the protein (9 mg/kg). Increases in PTD-HA-Bcl-xL were
clearly detectable at 1-2 hr after injection, peaked at 4-8 hr, and
were primarily retained at 24 hr (Fig. 2b).
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Figure 2.
In vivo protein transduction of
PTD-HA-Bcl-xL in murine brain. a, Western blotting with
either the anti-Bcl-x or anti-HA antibody detects the transduction of
PTD-HA-Bcl-xL into the cortex 4 hr after intraperitoneal injection of
the protein at various doses (left); the HA-Bcl-xL
protein lacking PTD failed to transduce across the blood-brain barrier
(right). In all blots, the fusion proteins serve as the
positive controls (PC). Immunoblotting of -tubulin
serves as a control for sample loadings (30 µg per
lane). Note that the endogenous Bcl-x proteins are
detectable in all brains. b, c, Quantitation of
PTD-HA-Bcl-xL transduction in the brain by ELISA. Intraperitoneal
injection of PTD-HA-Bcl-xL results in dose-dependent (b,
4 hr after injection) and time-dependent (c, injection
at the dose of 9 mg/kg) protein transduction into the murine cerebral
cortex. Data are mean ± SE (three animals per group).
*p < 0.05 versus controls; **p < 0.01 versus controls. d, Immunofluorescent detection
(using anti-HA antibody) of PTD-HA-Bcl-xL transduction in the
cortex/caudate (A) and hippocampal
(Hipp) formation (B) 4 hr after
intraperitoneal injection; the immunofluorescence is lost after
the primary antibody was preabsorbed with the fusion protein
(C). Injection of HA-Bcl-xL serves as the
negative control (Ctr) (D). In the
cerebral parenchyma, most of the cells transduced with PTD-HA-Bcl-xL
(HA immunoreactive; E, H, red) are
neurons, being immunoreactive for the neuronal markers NSE
(F, arrows in G; cortex) or
NeuN (I, arrows in J;
hippocampal dentate). Some astrocytes (GFAP-immunoreactive;
L, green) in the caudate are also
transduced (arrows in K-M).
Str, Striatum.
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Transduction of PTD-HA-Bcl-xL in the brain was evaluated at cellular
levels using immunohistochemistry at 4 hr after protein injection (9 mg/kg). As determined in the cortex, caudate-putamen, and hippocampus,
robust HA immunoreactivity was detected in most neurons throughout the
forebrain after injection of PTD-HA-Bcl-xL but not HA-Bcl-xL (Fig.
2d, A-C). Sections that were incubated in the
anti-HA antibody preabsorbed with PTD-HA-Bcl-xL resulted in loss of HA
immunoreactivity (Fig. 2d, D), thus confirming
the specificity of the detected immunoreactivity. Double-label
immunofluorescent staining revealed that in cerebral parenchyma, most
of the transduced cells were neurons (Fig. 2d,
E-J; NSE or NeuN positive); however, transduction also
occurred in some astrocytes in the caudate-putamen (Fig.
2d, K-M, GFAP positive). Astroglial transduction
of PTD-HA-Bcl-xL primarily occurred in astrocyte-enriched regions,
including vessel walls and white matter such as the corpus callosum
(data not shown).
In vivo systemic delivery of Bcl-xL fusion protein
protects against focal ischemic injury
MCA occlusion produced ipsilateral cerebral infarction averaging
~65 mm3 in volume, as determined
at 72 hr based on the loss of triphenyltetrazolium chloride (TTC)
staining (Fig. 3a).
Administration with PTD-HA-Bcl-xL but not HA-Bcl-xL or PTD-HA-GFP 2 hr
before the onset of ischemia reduced the infarct volume in a
dose-dependent manner (Fig. 3d). A significant reduction
averaging ~40% was reached at 9 mg/kg (p < 0.0001 vs vehicle controls), but an additional increase in the dose to
18 mg/kg did not result in an additional reduction in the infarct
volume. Cerebral salvage occurred primarily in the periphery of the
ischemic tissue, leading to enhanced survival of penumbral cortical
tissue. As determined at 24 hr after ischemia, PTD-HA-Bcl-xL (9 mg/kg)-treated animals showed improved neurological scores (Fig.
3c). Reduction of infarct size by PTD-HA-Bcl-xL (9 mg/kg)
was not accompanied by significant alterations in arterial blood
pressure and blood gases compared with control animals that received
vehicle alone (data not shown). As determined using laser-Doppler flowmetry, animals that received PTD-HA-Bcl-xL (9 mg/kg) or vehicle showed similar cortical blood flow changes during and after MCA occlusion (Fig. 3b). Delayed treatment with PTD-HA-Bcl-xL (9 mg/kg) continued to significantly reduce infarct volume when
administered at 5 or 45 min after the completion of ischemia, but the
effect was lost when protein injection was delayed by 120 min (Fig.
3d).
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Figure 3.
Systemic delivery of PTD-HA-Bcl-xL protects
against focal ischemic infarction. a, Representative
photographs of TTC-stained coronal sections of mouse brains recovered
from 90 min of focal ischemia and 72 hr of reperfusion. The sections
were chosen at the levels of 4 mm (top) and 6 mm
(bottom) from the anterior pole. The dotted white
lines illustrate the infarct border for each section.
b, Changes in cortical blood flow, as determined using
laser-Doppler flowmetry, are not different between fusion
protein-treated and vehicle-treated brains during or after ischemia
(n = 6 per group). CBF, Cerebral
blood flow. c, Neurological deficit scores in
vehicle-treated (Ve), PTD-HA-Bcl-xL-treated
(PTD-bcl), and HA-Bcl-xL-treated
(bcl) mice at 24 hr after ischemia.
Dots and columns represent the scores of
each animal and the mean scores, respectively. The neurological scores
were graded according to the scale described previously (Murakami et
al., 1998). d, Effects of intraperitoneal injection
ofPTD-HA-Bcl-xL on infarct volumes in the brain after 90 min
of focal ischemia. Vehicle (Veh), PTD-HA-Bcl-xL, or the
control proteins were injected at the indicated doses either 1 hr
before or at the indicated time after ischemia, and the infarct volume
was measured at 72 hr after ischemia. Data are mean ± SE;
n = 6-8 per group. *p < 0.05 versus vehicle treatment (ANOVA and post hoc Scheffe's
tests). The graph at the bottom
illustrates the comparison of infarct sizes in each brain section
between vehicle-treated and PTD-HA-Bcl-xL-treated mice.
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Bcl-xL fusion protein inhibits an apoptotic component of ischemic
neuronal death
To determine whether the protective effect of PTD-HA-Bcl-xL
against ischemic injury involves an anti-apoptotic mechanism, animals
treated with PTD-HA-Bcl-xL (9 mg/kg) or vehicle were subjected to MCA
occlusion, and the cerebral cortical tissues were assayed using the
DEVD-AFC cleavage assay for caspase-3-like activity at 3 and
24 hr after ischemia. In vehicle-treated animals, there were
significant increases in caspase-3-like activity at 3 hr and, to a
lesser extent, 24 hr after ischemia (Fig.
4a). However, the increased
caspase-3-like activity was almost completely attenuated in
PTD-HA-Bcl-xL-treated animals (p < 0.001). This
effect by PTD-HA-Bcl-xL was also confirmed by Western blotting. As
shown (Fig. 4b), the immunoreactivity for the active
caspase-3 (p17) was increased in the vehicle-treated but not the
PTD-HA-Bcl-xL-treated animals.
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Figure 4.
PTD-HA-Bcl-xL inhibits an apoptotic component of
ischemic neuronal death. a, Effects of PTD-HA-Bcl-xL on
caspase-3-like protease activity in the brain at 3 and 24 hr after
ischemia, as determined in the cortical cell extracts using the
fluorogenic substrate DEVD-AFC. Data are mean ± SE; n = 5 per group. **p < 0.01 versus vehicle treatment. b, Attenuation of
caspase-3 activation after ischemia by PTD-HA-Bcl-xL, as demonstrated
by Western blotting. The active (p17) caspase-3 fragment is increased
in the ischemic hemisphere (L) compared with the
nonischemic side (R) in vehicle-treated but not
in PTD-HA-Bcl-xL-treated brains. The blots are representative of three
independent experiments with similar results. c, Coronal
sections obtained from vehicle-treated and PTD-HA-Bcl-xL-treated
brains, respectively, 24 hr after ischemia. The red
boxes mark the approximate locations from which the
immunofluorescent images in c were obtained.
d, Representative immunofluorescent images show that
PTD-HA-Bcl-xL attenuates caspase-3 activation after ischemia.
Immunostaining was accomplished using the antibody recognizing the
active caspase-3. A-E, Low power (25×):
A, Nonischemic cortex. B, At 3 hr after
ischemia, caspase-3-immunoreactive cells are present primarily in
layers I-II and V of the cortex. C, The mounts of
caspase-3-immunoreactive cells are decreased in PTD-HA-Bcl-xL-treated
brain. D, 24 hr after ischemia, caspase-3-immunoreactive
cells are localized in the border zone of the infarction (*). The
dotted lines in D and E mark the
estimated infarct border. E, Few
caspase-3-immunoreactive cells are present in PTD-HA-Bcl-xL-treated
brain. F-I, high power (400×). Scale bar, 20 µM. F, At 3 hr after ischemia (vehicle
treated), caspase-3 immunoreactivity primarily shows a cytosolic
location. G, As indicated by the arrows, the
cells in F counterstained with the DNA dye PI.
H, At 24 hr after ischemia, caspase-3 immunoreactivity
is localized in the nucleus. I, As indicated by the
arrows, the cells in H counterstained with
PI. J-L, Double-label immunofluorescence of
PTD-HA-Bcl-xL (J) and caspase-3
(K) in the border zone of the cortical infarction
at 24 hr after ischemia (PTD-HA-Bcl-xL-treated brain); L
is the overlay of J and K. Note that
there is no colocalization of caspase-3 and PTD-HA-Bcl-xL in neurons
(L, arrows indicate protein-transduced
neurons). e, Apoptotic DNA fragmentation is attenuated
by PTD-HA-Bcl-xL after ischemia, as demonstrated by DNA
electrophoresis. The DNA was prepared from the cortical tissues 72 hr
after ischemia, using the brains pretreated with vehicle,
PTD-HA-Bcl-xL, or HA-Bcl-xL. The gel is representative of two
independent experiments with similar results.
|
|
The effect of PTD-HA-Bcl-xL on caspase-3 activation was also
demonstrated at the cellular level (Fig. 4d). Using the same antibody as that used in Western blots to detect active caspase-3, we
detected markedly increased immunofluorescence in neurons widely distributed in the frontoparietal cortex 3 hr after ischemia in vehicle-treated animals (Fig. 4d, B,D), and the
signals were localized primarily in the cytosol of neurons (Fig.
4d, F,G). At 24 hr after ischemia, caspase-3
immunofluorescent cells were distributed primarily in the border zone
of cortical infarction, and the immunofluorescence was present
primarily in the nucleus of the neurons (Fig. 4d, H,I). These results confirm previous findings by
others in a similar animal model (Namura et al., 1998). In contrast,
the amounts of caspase-3 immunofluorescent neurons were greatly
decreased in the cerebral cortex in PTD-HA-Bcl-xL-treated animals at
both postischemic time points (Fig. 4d, C,E).
Double-label immunofluorescent staining revealed that there was no
colocalization of caspase-3 and PTD-HA-Bcl-xL immunofluorescence within
the protected cortex after ischemia (Fig. 4d,
J-L), further confirming the anti-apoptotic effect of PTD-HA-Bcl-xL protein transduction in the ischemic brain.
| |
DISCUSSION |
Using recombinant technology, we produced a biologically active
Bcl-xL fusion protein containing the PTD that allows the in vivo delivery of the protein across the blood-brain barrier and robust protein transduction in the brain. The death-suppressing effect
of this fusion protein was initially confirmed in primary cultures of
cortical neurons, in which PTD-HA-Bcl-xL but not HA-Bcl-xL or
PTD-HA-GFP inhibited STS-induced apoptosis in both dose-dependent and
time-dependent manners. When PTD-HA-Bcl-xL was injected
intraperitoneally, the protein was efficiently transduced into brain
cells within 2-4 hr. The PTD-HA-Bcl-xL-transduced brains but not
control protein-treated brains showed significantly decreased infarct
sizes after 90 min of focal ischemia, and this protective effect was
detectable when the protein was administered before or 45 min after
ischemia. Furthermore, ischemia-induced activation of caspase-3 was
markedly attenuated in PTD-HA-Bcl-xL-transduced brains. These results
provide the first evidence that brain transduction of a nonsecretory
protein engineered to contain the PTD shows biological activity and
protects the brain against ischemic/reperfusion injury.
The data presented herein demonstrate that the PTD-HA-Bcl-xL protein
was transduced efficiently into neurons in vitro and in vivo. The fusion protein contains an HA tag, which allows
immunodetection of the transduced protein to be distinguished from
endogenous Bcl-xL. When directly applied to the culture media,
PTD-HA-Bcl-xL was detected in ~100% of the neurons within 15 min
(Fig. 1). This observation confirms the reported capability of PTD to
help achieve rapid protein transduction in mammalian cells (Nagahara et
al., 1998; Schwarze et al., 1999). Notably, the death-suppressing
effect of PTD-HA-Bcl-xL in neurons was equally potent when the protein was added either 4 hr before or 1 hr after STS exposure. This suggests
that the transduced protein can rapidly achieve its biological activity
in neurons, presumably through chaperone-mediated conformational changes, and that its death-suppressing efficacy is stable. The recent
study by Liu et al. (2001) showed a similar death-suppressing effect by
a Bcl-xL fusion protein, LFn-Bcl-xL, against STS-induced apoptosis in
rat cerebellar granule cells and macrophages, in which Bcl-xL was fused
into a 254 aa nontoxic derivative (LFn) of anthrax toxin. The
transduction of LFn-Bcl-xL requires the action of another anthrax toxin
component, protective antigen (Liu et al., 2001), which binds to an
unidentified cell surface receptor and subsequently transports LFn into
cells (Friedlander, 1986). Compared with the anthrax toxin delivery
system, the PTD transduction system described in this study may have
several advantages. First, the PTD consists of only 11 aa, which does
not substantially increase the particle mass of the fusion protein.
Second, the transduction of PTD-containing fusion protein does not
require a helper protein. Third, the PTD mediates protein transduction by targeting the lipid bilayer component of the cell membrane; thus,
theoretically, a protein containing PTD may be transduced into all
mammalian cell types (Schwarze et al., 1999).
The cellular transduction of PTD-HA-Bcl-xL in murine
brain and its protective effect against focal stroke are robust. Using quantitative ELISA, we detected ~4 ng of PTD-HA-Bcl-xL (per milligram of tissue protein) in the cortex within 2 hr after systemic injection (9 mg/kg), which was within the range of the effective concentrations of PTD-HA-Bcl-xL in cultures against STS-induced apoptosis. At the
dosage of 9 mg/kg, we demonstrated that administration of PTD-HA-Bcl-xL
resulted in an up to ~40% reduction in infarct sizes 72 hr after
focal ischemia. This efficacy likely resulted from the direct
protection by PTD-HA-Bcl-xL, because the protection occurred without
altering cortical blood flow, body temperature, or other physiological
parameters during or after ischemia.
The protective effect by PTD-HA-Bcl-xL against ischemic injury may be
mediated by several mechanisms. There is clear evidence that
PTD-HA-Bcl-xL prevented caspase-3 activation in the ischemic brain
(Fig. 4). This effect by PTD-HA-Bcl-xL could be the consequence of its
inhibitory effect on cytochrome c release from mitochondria and/or its direct interaction with the Apaf-1/caspase-9 apoptosome, because both mechanisms are upstream of caspase-3 activation and appear
to be major targets for Bcl-xL (Kluck et al., 1997; Hu et al., 1998;
Pan et al., 1998). Furthermore, there is strong evidence that these
mechanisms may participate in the molecular cascade leading to
neuronal apoptosis after cerebral ischemia (Fujimura et al., 1999;
Sugawara et al., 1999; Noshita et al., 2001; Cao et al., 2002).
Moreover, PTD-HA-Bcl-xL could block mitochondrial release of other
apoptogenic factors such as apoptosis-inducing factor; the
latter may mediate ischemic cell death via caspase-independent mechanisms (Graham and Chen, 2001). Finally, the speculative role for
Bcl-xL in protecting against hypoxia-induced necrosis (Tsujimoto et
al., 1997) may have particular relevance in explaining its potent
death-suppressing effect demonstrated in this study, because it is very
likely that ischemic neuronal death involves both apoptotic and
necrotic mechanisms.
The significance of the results documented in this report is twofold.
First, the powerful capability of the PTD in accelerating in
vivo protein transduction in the brain and in cultured neurons provides an excellent tool for mechanistic studies, through which many
important biological issues such as cell death pathways or signal
transduction mechanisms in the CNS can be addressed. Second, the PTD
recombinant technology will allow us to screen a large number of
potentially potent peptide neuroprotectants in animal models of stroke
or other neurological disorders, which may have clinical implications
as a novel molecular therapeutic intervention.
| |
FOOTNOTES |
Received Feb. 8, 2002; revised April 1, 2002; accepted April 15, 2002.
This work was supported by National Institutes of Health Grants
NS38560, NS36736, and NS35965 to J.C., from the National Institute of
Neurological Disorders and Stroke. J.C. is a recipient of the Established Investigator Award from the American Heart Association. J.C. and S.H.G. were also supported in part by the Geriatric Research, Education and Clinical Center, Veterans Affairs Pittsburgh Health Care
System (Pittsburgh, PA). We thank Cristine O'Horo for technical assistance, Carol Culver for editorial assistance, and Pat Strickler for secretarial support.
Correspondence should be addressed to Dr. Jun Chen, Department of
Neurology, S-507, Biomedical Science Tower, University of Pittsburgh
School of Medicine, Pittsburgh, PA 15213. E-mail: jun{at}med.pitt.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
