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The Journal of Neuroscience, April 1, 1998, 18(7):2387-2398
Degeneration In Vivo of Rat Hippocampal Neurons by
Wild-Type Alzheimer Amyloid Precursor Protein Overexpressed by
Adenovirus-Mediated Gene Transfer
Isao
Nishimura1,
Taichi
Uetsuki1,
Sergio U.
Dani1,
Yoshiyuki
Ohsawa2,
Izumu
Saito3,
Hitoshi
Okamura4,
Yasuo
Uchiyama2, and
Kazuaki
Yoshikawa1
1 Division of Regulation of Macromolecular Functions,
Institute for Protein Research, Osaka University, Suita, Osaka 565, Japan, 2 Department of Anatomy, Osaka University Medical
School, Suita, Osaka 565, Japan, 3 Laboratory of Molecular
Genetics, Institute of Medical Science, University of Tokyo, Minato-ku,
Tokyo 108, Japan, and 4 Department of Anatomy and Brain
Science, Kobe University School of Medicine, Chuo-ku, Kobe 650, Japan
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ABSTRACT |
In an attempt to elucidate the pathological implications of
intracellular accumulation of the amyloid precursor protein (APP) in
postmitotic neurons in vivo, we transferred APP695 cDNA
into rat hippocampal neurons by using a replication-defective
adenovirus vector. We first improved the efficiency of
adenovirus-mediated gene transfer into neurons in vivo
by using hypertonic mannitol. When a  -galactosidase-expressing
recombinant adenovirus suspended in 1 M mannitol was
injected into a dorsal hippocampal region, a number of neurons in
remote areas were positively stained, presumably owing to increased
retrograde transport of the virus. When an APP695-expressing adenovirus
was injected into the same site, part of the infected neurons in the
hippocampal formation underwent severe degeneration in a few days,
whereas astrocytes near the injection site showed no apparent
degeneration. These degenerating neurons accumulated different epitopes
of APP, and /A4 protein (A)-immunoreactive materials were
undetected in the extracellular space. A small number of degenerating
neurons showed nuclear DNA fragmentation. Electron microscopic
examinations demonstrated that degenerating neurons had shrunken
perikarya along with synaptic abnormalities. Microglial
cells/macrophages were often found in close proximity to degenerating
neurons, and in some cases they phagocytosed these neurons. These
results suggest that intracellular accumulation of wild-type APP695
causes a specific type of neuronal degeneration in vivo
in the absence of extracellular A deposition.
Key words:
Alzheimer's disease; amyloid precursor protein; neurodegeneration; apoptosis; microglia; synapse; hippocampus; hypertonic mannitol; adenovirus vector
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INTRODUCTION |
Alzheimer's disease (AD) is a
neurodegenerative disease characterized by massive amounts of neuronal
death associated with prominent histopathological features such as
extracellular deposition of amyloid fibrils and accumulation of
intracellular neurofibrillary tangles. The principal component of the
extracellular amyloid fibrils is /A4 protein (A) (Glenner and
Wong, 1984 ), which is derived from the amyloid precursor protein (APP)
(Kang et al., 1987). APP is thought to be a membrane-associated
protein, but the extracellular domain is secreted after proteolytic
cleavage in the interior of A (Esch et al., 1990). Differentiated
postmitotic neurons express abundant APP mRNA, especially APP695 mRNA
(Yoshikawa et al., 1990), but do not process significant amounts by
secretory cleavage (Hung et al., 1992). APP is transported to synaptic
sites by the fast anterograde component (Koo et al., 1990). Although the physiological implications of APP in neurons have not yet been
fully elucidated, it is inferred that pathological accumulations of APP
within neurons cause physiological functions such as synaptic transmission and signal transduction to deteriorate.
Previous histopathological studies have demonstrated that
APP-immunoreactive materials are accumulated within neurons in the brain affected by AD (Benowitz et al., 1989; Cole et al., 1991; Cummings et al., 1992). These observations suggest that intracellular accumulation of APP is related to the pathogenesis of AD. However, it
remains unclear whether degenerating neurons in AD brain accumulate APP
abnormally or conversely whether intracellular APP accumulations cause
neuronal degeneration. We have previously demonstrated that overexpression of full-length APP induces degeneration in
vitro of postmitotic neurons derived from embryonal carcinoma
cells (Yoshikawa et al., 1992). These neurons intracellularly
accumulate APP C-terminal fragments, which are also toxic to
glioma-derived cells (Hayashi et al., 1992). Moreover, an APP
C-terminal 100 amino acid residue fragment, which includes the entire
A domain, forms amyloid fibril-like structures within transfected
cells (Maruyama et al., 1990). These observations prompted us to
examine whether overexpression of wild-type APP induces cellular
degeneration in vivo in the brain of experimental animal
models.
Replication-defective adenovirus vectors have been used to transfer
foreign genes directly into the brain parenchyma (Akli et al., 1993;
Bajocchi et al., 1993; Davidson et al., 1993; Le Gal La Salle et al.,
1993). In these experiments, various cell types such as vascular
endothelial cells, glial cells, and neurons are infected with
recombinant adenoviruses. Here we demonstrate, using an improved method
for in vivo adenovirus-mediated gene transfer, that
overexpression of APP695 induces rapid degeneration of neurons in
vivo. APP-immunoreactive materials were accumulated within the
degenerating neurons, and A immunoreactivity was undetected in the
extracellular space, suggesting that neurons in vivo are vulnerable to intracellular accumulation of APP in the absence of
extracellular A deposition.
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MATERIALS AND METHODS |
Cosmid construction. Recombinant adenoviruses for
expression of LacZ and APP 695 were constructed using cassette cosmids
pAxcw and pAxCAwt, respectively (Miyake et al., 1996). LacZ
transcription unit driven by the CAG promoter (Niwa et al., 1991) was
inserted into pAxcw at the SwaI site (designated pAxCALacZ).
Full-length cDNA of human APP 695 (Kang et al., 1987; Yoshikawa et al.,
1992) was blunt-ended and inserted into pAxCAwt at the SwaI site
(designated pAxCAYAP), so that the inserted cDNA is transcribed under
the control of CAG promoter. The recombinant viruses were prepared according to the method described previously (Miyake et al., 1996). Briefly, cosmid DNA was co-transfected with the EcoT221-digested DNA-terminal protein complex of Ad5-dlX into 293 cells to generate the
recombinant viruses by homologous recombination. The recombinant viruses, designated AxCALacZ (for LacZ expression) and AxCAYAP (for APP
expression), were propagated in 293 cells. After the third propagation,
virions were extracted from 293 cells, purified by double cesium
step-gradient purification (Kanegae et al., 1994), dialyzed against a
vehicle solution containing 10% glycerol in PBS, pH 7.4, and stored at
 80°C. The titers of recombinant viruses were determined by the
modified end-point cytopathic effect assay on 293 cells (Kanegae et
al., 1994) and expressed in plaque-forming units (pfu). Positive
expression of the inserted gene product was confirmed by
immunohistochemical detection using COS-1 cells or NIH 3T3 cells.
Experiments using recombinant adenovirus were approved by the
Recombinant DNA Committee of the Osaka University and performed
according to institutional guidelines.
Gene delivery to the hippocampus and tissue preparation. One
hundred forty-four male Wistar rats (Nippon SLC, Shizuoka, Japan) weighing 220-250 gm were used: 46 rats for -galactosidase (-gal) expression and 98 rats for APP expression. The rats were anesthetized with sodium pentobarbital and secured on a stereotactic platform (Narishige, Tokyo). Using sterile techniques, we exposed the skull and
made a 2 mm burr hole. Through the burr hole, a fine glass micropipette
attached to a 5 µl Hamilton microsyringe was unilaterally introduced
into the dorsal region of the left hippocampus according to the brain
atlas of Paxinos and Watson (1986) (stereotactic coordinates: anterior,
4.5 mm caudal to bregma; lateral, 2.7 mm left lateral to midline;
ventral, 3.2 mm ventral to dural surface at toothbar setting at ~1-2
mm below the interaural line). Five microliters of AxCALacZ or AxCAYAP
suspended in 1 M mannitol solution diluted in PBS were
administered over a 10 min period. The adenovirus-injected rats showed
neither apparent abnormal behaviors nor seizures.
Histochemistry and immunohistochemistry. Virus-infected rats
were anesthetized deeply and fixed by intracardiac perfusion with 4%
paraformaldehyde in 0.1 M phosphate buffer (PB), pH 7.4. The brains were then removed and post-fixed with the same fixative overnight. After cryoprotection with 20% sucrose in 0.1 M
PB, horizontal 30-µm-thick sections were prepared and used for
staining. For histochemistry for -gal, cryosections were washed with
PBS and stained by immersion in 5 mM
K3Fe(CN)6, 5 mM
K4Fe(CN)6, 2 mM
MgCl2, 0.01% sodium deoxycholate, 0.02% Nonidet
P-40, and 2 mg/ml 5-bromo-4-chloro-3-indolyl--galactoside (X-gal) in
PBS at 37°C overnight. Sections were then washed with PBS and placed onto gelatin-coated slides. The sections were counterstained with eosin
and mounted with mounting media (Mount-Quick; Daido Sangyo, Tokyo)
after dehydration through a graded series of ethanol. For immunohistochemistry, cryosections were incubated at 4°C for 2 d
with the following antibodies in PBS containing 0.1% Triton-X: rabbit
anti--gal serum (1:1000) (5 Prime 3 Prime, West Chester, PA),
rabbit antiserum against the C-terminal 25 amino acid residues of APP
(671-695) (AC-1) (Yoshikawa et al., 1992) (1:500), rabbit antiserum
against the A (1-24) amino acid residues (Rb758) (Ishii et al.,
1989) (1:500), mouse monoclonal anti-NeuN antibody (A60) (Mullen et
al., 1992) (1:50), mouse monoclonal antibody against glial fibrillary
acidic protein (GFAP) (1:5000), and mouse monoclonal antibody against
the amino terminus of APP (P2-1) (Van Nostrand et al., 1989) (1:500).
After the sections were rinsed thoroughly, they were incubated at 4°C
overnight with rhodamine B- or fluorescein isothiocyanate
(FITC)-conjugated goat anti-rabbit IgG (1:200) (Tago, Burlingame, CA)
for rabbit antibodies and with FITC- or rhodamine B-conjugated goat
anti-mouse IgG (1:200) (Tago) for mouse antibodies. Immunoreactivities
were visualized with a fluorescence microscope (BX 50- 34-FLAD 1, Olympus, Tokyo) or with a confocal laser scanning microscope
(LSM-GB200, Olympus). To identify microglial cells, the cryosections
were stained with 20 µg/ml Griffonia simplicifolia lectin-FITC conjugate (Sigma, St. Louis, MO) in PBS containing 0.1%
Triton X-100 at room temperature for 2 hr (Streit, 1990). To examine
the association of microglia and APP (or -gal)-overexpressing neurons, the sections were doubly stained for Griffonia
lectin and APP (or -gal) immunoreactivity.
Western blot analysis. Four days after viral inoculation,
the bilateral hippocampi were removed from the rat. The gross regions (~10 mg wet weight) were dissected from the injection site, and two
control areas: rostral areas of the ipsilateral (distant from the
injection site) and contralateral hippocampi. The tissues were
homogenized, sonicated for 30 sec in a lysis buffer (0.5% Nonidet
P-40, 0.1% sodium lauryl sulfate, 10 µM
phenylmethanesulfonyl fluoride), and centrifuged at 20,000 × g for 10 min. The samples (20 µg protein) were separated
by 10% SDS polyacrylamide gels and immunoblotted with the antibodies
AC-1 and P2-1. For detection of A peptides, the tissue samples (20 µg protein) and synthetic A1-40 (100 ng) (Sigma) were separated
by a 14% Tris-Tricine SDS polyacrylamide gel and immunoblotted with
the antibody Rb758 (Hayashi et al., 1992).
Quantification of the degenerating neurons. AxCALacZ or
AxCAYAP (each 3.7 × 107 pfu/5 µl) was
injected into the dorsal hippocampus. Intrahippocampal regions (the
subiculum, CA3 pyramidal cell layer, hilus of the dentate gyrus, and
granule cell layer of the dentate gyrus) distant from the injection
site were selected for the analysis. Four days after viral
inoculation, degenerating neurons among -gal- and APP-immunopositive
neurons (>20 immunopositive cells) in each region were counted. The
degenerating neurons were identified with those showing at least one of
the following morphological abnormalities: irregular contour of soma,
distortion or dilatation of processes, and disorganized intracellular
membrane. Statistical significance of the results was assessed using
Student's t test.
DNA nick-end labeling. The nuclei of the APP-overexpressing
cells were labeled by the terminal deoxynucleotidyl transferase (TdT)-mediated dUTP-biotin nick-end labeling (TUNEL) reaction according
to the modified method of Gavrieli et al. (1992). Briefly, after
treatment with 0.3% H2O2 in methanol for 30 min, they were incubated with 100 U/ml TdT (Takara, Tokyo) and 10 µM biotin-16-dUTP (Boehringer Mannheim, Mannheim,
Germany) in TdT buffer (100 mM sodium cacodylate, pH 7.0, 1 mM cobalt chloride, 50 µg/ml gelatin) at 37°C for 2 hr.
DNA fragmentation was detected by the peroxidase-conjugated avidin-biotin complex method (Vector Laboratories, Burlingame, CA)
using 3, 3'-diaminobenzidine tetrahydrochloride (DAB), and the reaction
was enhanced with sulfate nickel ammonium. After TUNEL reaction, the
sections infected with AxCAYAP and AxCALacZ were immunostained with the
antibody AC-1 and anti--gal serum, respectively, as described above.
The FITC fluorescence for APP (or -gal) immunoreactivity and the
peroxidase-stained DNA fragmentation in the same fields were visualized
with the fluorescence microscope.
Electron microscopy. Virus-infected rats were anesthetized
deeply and fixed by intracardiac perfusion with 2% paraformaldehyde, 2% glutaraldehyde in 0.1 M PB. The brain tissues were cut
into ~1-mm-thick blocks, including the left hippocampal formation. The specimens were then post-fixed with 2% osmium tetroxide in 0.1 M PB, dehydrated with a graded series of ethanol, and
embedded in Epon 812. Degenerating neurons were identified on semithin sections stained with 1% toluidine blue, and then ultrathin sections containing these neurons were cut with an ultramicrotome (Ultracut N,
Reichert-Nissei, Tokyo) and mounted on copper grids. After they were
stained with a saturated aqueous solution of uranyl acetate and lead
citrate, the sections were observed with an electron microscope
(H-7100, Hitachi, Tokyo).
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RESULTS |
Efficient adenovirus-mediated gene transfer into in
vivo neurons
We injected the recombinant adenovirus containing the LacZ cDNA
(AxCALacZ) (6.3 × 107 pfu/5 µl) suspended in
PBS into the parenchyma of the rat cerebral cortex. We found that
vascular endothelial cells and glia-like cells were efficiently
infected, but only a few neurons near the injection site were labeled
(data not shown). Thus, we inferred that these non-neuronal cells, like
those consisting of the blood-brain barrier (BBB), prevent the virus
from entering neurons. In an attempt to increase the viral
accessibility to neurons, we used hypertonic mannitol, which is often
applied to the transient opening of the BBB by intracarotid
administration (Muldoon et al., 1995). For determination of infected
neurons, the hippocampal formation was used as a model system, because
neuronal types and their connections in this structure are well
defined. Moreover, the hippocampal formation is one of the regions in
which neurons are severely affected by AD (Esiri et al., 1997).
The adenovirus AxCALacZ suspended in 1 M mannitol was
stereotactically injected into a left dorsal hippocampus, and the
tissues were examined 4 d after viral inoculation. When
AxCALacZ-infected cells in the horizontal sections were visualized by
X-gal histochemistry, the majority of intensely stained cells were
neuron-like cells in the granule cell layer of the dentate gyrus (Fig.
1A). Moreover, a number
of cells in remote areas such as the Ammon's horn (CA) 3 region (Fig.
1C), perforant pathway (Fig. 1E), and
ipsilateral entorhinal cortex (Fig. 1G) were intensely
stained. On the other hand, only a few cells in these regions were
positively stained when injected with isotonic PBS (Fig.
1B,D,F,H).
The infected cells were then characterized by double immunostaining for
-gal and NeuN, a neuronal nuclear marker (Mullen et al., 1992) (Fig. 2). In the hilus of the dentate gyrus,
all of the -gal-immunopositive cells were neurons with
NeuN-immunoreactive nuclei, and no -gal-immunopositive glia-like
cells were detected (Fig. 2A,B).
Moreover, a group of the NeuN-immunoreactive neurons in the subiculum
and CA3 regions of the ipsilateral hippocampus were also infected (data
not shown). -gal-immunopositive neurons in intrahippocampal regions
were morphologically intact. In the ipsilateral entorhinal cortex, a
group of medium- to large-sized NeuN-immunoreactive neurons in layers
II and III were immunopositive for -gal, whereas small neurons in
deep layers were hardly stained (Fig. 2C,D).
Neurons in the layer II project their axons into the dentate gyrus via the perforant pathway, which was also intensely stained (Fig. 1E). Therefore, it is inferred that this specific
group of neurons in the ipsilateral entorhinal cortex takes up the
virions at the injection site and transports them to the somata in a
retrograde manner.
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Figure 1.
Enhancement of adenovirus infectivity in
vivo by hypertonic mannitol. AxCALacZ (6.3 × 107 pfu/5 µl) suspended in 1 M
mannitol (A, C, E, G) or in isotonic PBS (B, D,
F, H) was stereotactically injected into the left dorsal hippocampus. Five days later, infected cells were histochemically detected for -gal activity (X-gal staining). A, B,
The dentate gyrus of the hippocampus; C, D, the
pyramidal cell layer of the CA3 region; E, F, the
perforant pathway; G, H, the ipsilateral entorhinal
cortex (layer II). Arrows point to the regions above for
orientation. Scale bar (shown in H for
A-H): 200 µm.
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Figure 2.
Identification of infected cells as neurons.
AxCALacZ (6.3 × 107 pfu/5 µl) suspended in 1 M mannitol was injected into the left dorsal hippocampus,
and infected cells were stained by fluorescent immunohistochemistry for
-gal (A, C) and NeuN
(B, D). A,
B, The hilus of the dentate gyrus. All of the
-gal-immunopositive cells possess NeuN-immunoreactive nuclei;
C, D, the ipsilateral entorhinal cortex.
Note that many neurons in superficial layers (layers II and III) are
infected. Arrowheads in
A-D point to representative neurons
expressing both exogenous -gal (A, C)
and endogenous NeuN (B, D). Scale bar
(shown in A for A-D): 100 µm.
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To examine whether the increased infectivity is dependent on the
tonicity of the vehicle solution, we quantified the infected neurons in
serial 30-µm-thick sections of the ipsilateral entorhinal cortex
after injecting AxCALacZ with isotonic PBS, 0.2 M mannitol, 1 M mannitol, and 1 M sucrose. The maximal
numbers of infected neurons were more than 70 per section in 1 M mannitol-treated and 1 M sucrose-treated
samples, whereas a few neurons (less than five per section) were
infected with the virus suspended in isotonic PBS and 0.2 M
mannitol (data not shown). These findings indicate that hypertonic
solutions increase the efficiency of neuronal infection.
Adenovirus-mediated transfer of APP cDNA into the hippocampus
Using the modification with hypertonic mannitol, we transferred
the recombinant adenovirus carrying cDNA encoding human APP 695 (AxCAYAP), which is abundantly expressed in postmitotic neurons (Yoshikawa et al., 1992), into hippocampal neurons in vivo.
We first analyzed exogenous APP expression in the infected region by
Western blotting (Fig. 3). A gross
region, including the injection site, contained higher levels of ~110
kDa APP-immunoreactive molecules than those of control regions, as
detected with an antibody against APP C-terminus (Fig. 3A,
APP-C). Antibody P2-1, a monoclonal antibody raised against
native human APP (nexin-2) (Van Nostrand et al., 1989), reacted with
exogenous human APP expressed at the injection site but not with
endogenous rat APP (Fig. 3A, APP-N). APP
C-terminus-immunoreactive degraded fragments, which were generated in
APP-overexpressing P19 cells (Yoshikawa et al., 1992), were hardly
detected in vivo 4 d after viral infection. In
addition, ~4 kDa A immunoreactive materials were undetected in the
AxCAYAP-infected region (Fig. 3B, A). These
results suggest that AxCAYAP-infected cells contain human APP695 as a
full-length form without being processed further into smaller
fragments.
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Figure 3.
Western blot analysis of APP and A expressed in
AxCAYAP-infected hippocampal regions. AxCAYAP suspended in 1 M mannitol was stereotactically injected into the dorsal
hippocampus. Four days later, gross regions including the injection
site and distant regions (as controls) were dissected. APP was detected
by Western blotting with the antibodies AC-1 (APP-C),
P2-1 (APP-N), and Rb758 (A).
R, A rostral region of the ipsilateral hippocampus;
I, a dorsal hippocampal region including the injection
site; C, a contralateral dorsal hippocampal region;
S, synthetic A1-40 standard (100 ng). Molecular
weight markers are on the left. Arrows
indicate predicted positions of full-length APP and A1-40.
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We then infected equal amounts of AxCAYAP and AxCALacZ (each
2.4 × 107 pfu/5 µl) into the dorsal
hippocampus and examined the infected tissues by immunohistochemistry.
Some neurons in the hilus of the dentate gyrus showed -gal
immunoreactivity (Fig.
4A), whereas very few
neurons possessed APP immunoreactivity (Fig. 4B). On the other hand, many glia-like cells near the injection site contained large amounts of both -gal and APP-immunoreactive materials (Fig. 4A,B). This discrepancy may be because exogenous APP
in the infected neurons is metabolized more intensively than -gal,
whereas both APP and -gal are slowly metabolized in the infected
glial cells. When a larger amount of AxCAYAP (3.7 × 107 pfu/5 µl) was injected, intensely
APP-immunoreactive cells were detected at the stratum radiatum (Fig.
4C). In this region, APP-immunopositive neuron-like cells
appeared to be degenerating, whereas APP-immunopositive glia-like cells
were apparently intact. A number of APP-immunoreactive neurons were
found in the ipsilateral entorhinal cortex, but they showed little or
no degeneration (Fig. 4D). The subiculum of the hippocampus contained some degenerating neurons, as identified by
double immunostaining for APP and NeuN (Fig.
4E,F). Degenerating neurons
were consistently found in intrahippocampal regions, including the
stratum radiatum, stratum lucidum, hilus and granule cell layer of the
dentate gyrus, subiculum, and CA3 when infected with AxCAYAP (3.7 × 107 pfu/5 µl) (data not shown). On the other
hand, APP-accumulating astrocytes, identified as GFAP-immunopositive
cells, near the injection site showed no apparent degenerative changes
(Fig. 4G,H). In the following experiments,
the amount of 3.7 × 107 pfu/5 µl of AxCAYAP
was used.
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Figure 4.
APP-accumulating cells in adenovirus-infected
brain regions. AxCAYAP plus AxCALacZ (each 2.4 × 107 pfu/5 µl) (A, B), or AxCAYAP
(3.7 × 107 pfu/5 µl)
(C-H) suspended in 1 M mannitol was
stereotactically injected into the dorsal hippocampus. Four days later,
immunoreactivities of -gal (A), APP C terminus
(B-E, G), NeuN (F),
and GFAP(H) were examined.
A (-gal) and B (APP), the hilus of the
dentate gyrus (adjacent sections); C (APP), the stratum
radiatum; D (APP), the ipsilateral entorhinal cortex;
E (APP) and F (NeuN), the subiculum of
the hippocampus; G (APP) and H (GFAP),
the dentate gyrus. Arrows in A point to
representative -gal-immunopositive neurons. Arrows in
E and F indicate the APP-immunoreactive
degenerating neuron. Arrows in G and
H point to APP-accumulating astrocytes. Scale bar (shown
in A): A, B, 200 µm;
C, 100 µm; D-H, 50 µm.
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When morphological changes of APP-accumulating neurons in the
hippocampus were examined 5 d after AxCAYAP injection, many neurons contained varying amounts of intracellular APP-immunoreactive materials. Some degenerating neurons with irregular contours had APP-immunoreactive granules in both the perikarya and the dilated processes (Fig. 5A,B).
Moreover, disorganized APP-immunoreactive membranes (Fig.
5C) and "ghost-like" depositions of APP-immunoreactive granules were detected (Fig. 5D). Such severely degenerating
neurons were undetected in the tissues infected with the same amount of LacZ-carrying adenovirus (Fig. 5F). When the infected
tissue samples were examined on days 5, 10, 15, 20, and 30 after viral
infection, APP-accumulating neurons in the hilus disappeared on day 15 or later (data not shown), and only weakly APP-immunoreactive cells, presumably glial cells, were found in the dentate gyrus on day 15 (Fig.
5E). These findings raise the possibility that intracellular accumulations of APP induce rapid neuronal death without leaving APP-immunoreactive debris in vivo. To examine the
specificity of APP-induced neurodegeneration, we quantified the
degenerating neurons in the hippocampus infected with AxCAYAP or
AxCALacZ (Table 1). The hippocampal
regions distant from the injection site were selected to avoid
nonspecific neurodegeneration caused by tissue damage. In each region
tested, the number of degenerating APP-immunoreactive neurons was
significantly larger than that of degenerating -gal-immunoreactive neurons. In the dentate gyrus near the injection site, a larger number
of -gal-immunopositive neurons showed degenerative changes, but the
APP-induced neurodegeneration was significantly frequent. In this
analysis, degrees of degeneration of AxCAYAP-infected neurons were much
greater than those of AxCALacZ-infected neurons (data not shown). These
results suggest that AxCAYAP-induced neurodegeneration is caused by
overexpression of APP and not by nonspecific neurotoxicity of
adenovirus.
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Figure 5.
Degeneration of APP-accumulating hippocampal
neurons. AxCAYAP was injected into the dorsal hippocampus. Tissues were
stained with antibody AC-1 (A-E) and
anti--gal antibody (F) on day 4 (A-D, F) and day 15 (E). The regions examined are A, C,
D, F, the hilus of the dentate gyrus; B, the
stratum lucidum; E, the granule cell layer of the
dentate gyrus. Highly APP-immunoreactive materials are detected in the
perikarya (arrows in A), dilated neurites
(arrows in B), deformed intracellular
membranes (arrows in C),
and amorphous extracellular depositions (arrow in
D). Very weak APP-immunoreactive materials are detected
in the dentate gyrus on day 15 (E). Most
of the -gal-immunopositive neurons show no apparent degeneration
(F). Scale bar (shown in
A): A, C, D, F, 20 µm; B,
E, 50 µm.
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We immunostained these degenerating neurons with antibodies against
different epitopes of APP. Confocal laser microscopy revealed that the
N- and C-terminal epitopes of APP showed closely similar distribution
patterns (Fig.
6A,B).
This, together with the data of Western blot analysis (Fig. 3),
suggests that these degenerating neurons contain a full-length form of
APP695. Degenerating neurons were then doubly stained for APP
N-terminal and A1-24 epitopes. A immunoreactivity was detected
in degenerating neurons with intense APP N-terminus-immunoreactivity,
but some APP-immunopositive cells contained no A-immunoreactive
materials (Fig. 6C,D). In the extracellular space
adjacent to APP-immunopositive degenerating neurons,
A-immunoreactive materials were undetected.
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Figure 6.
Distribution of different epitopes of APP in
AxCAYAP-infected tissues. AxCAYAP was injected into the dorsal
hippocampus. Four days later, the sections of the hilus of the dentate
gyrus were immunostained for the N terminus (A,
C), the C terminus
(B) of APP, and A 1-24
(D). Fluorescent images were visualized with a
confocal laser microscope. APP N and C terminus show similar distribution patterns (A, B). Note the cells containing
both APP N-terminal and A immunoreactivities (arrows
in C, D) and the N-terminus-immunoreactive cells lacking
A immunoreactivity (arrowheads). Scale bars (shown in
B and D for A-D): 20 µm.
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To examine whether DNA fragmentation occurs during degeneration of
APP-accumulating neurons, we doubly stained the cells by the APP
immunohistochemistry and TUNEL method. We found that some APP-accumulating degenerating neurons (<20%) possessed TUNEL-positive nuclei (Fig.
7A-D). In
contrast, all -gal-accumulating neurons (i.e., a negative control)
had TUNEL-negative nuclei (Fig. 7E,F), whereas CA1
pyramidal neurons of the gerbil hippocampus after transient ischemia
(Nitatori et al., 1995) (i.e., a positive control) showed numerous
TUNEL-positive nuclei (Fig. 7G). To examine whether microglial cells/macrophages are involved in scavenging process for
these degenerated neurons, we doubly stained the APP-accumulating cells
with the antibody against the APP C terminus and Griffonia lectin, a marker for microglia (Streit, 1990) (Fig.
8). Microglial cells were often found in
close proximity to the APP-accumulating degenerating neurons, and some
of them appeared to phagocytose these degenerating neurons (Fig.
8A,B). In the tissues infected with
AxCALacZ, no microglial cells associated with -gal-immunoreactive neurons were detected (Fig. 8C,D).
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Figure 7.
Nuclear DNA fragmentation in APP-accumulating
neurons. AxCAYAP was injected into the dorsal hippocampus. Four days
later, the sections of the stratum lucidum were doubly stained for APP C-terminus (A, C) and TUNEL reactivity (B,
D). Note the APP-accumulating neurons with
(arrow) and without (arrowhead)
TUNEL-positive nuclei (A, B), and TUNEL-reactive
granular materials spread throughout APP-accumulating soma (C,
D). E, F (negative control), the pyramidal cell
layer of CA3 region infected with AxCALacZ, doubly stained for -gal
(E) and TUNEL (F).
Arrows in E and F point to
-gal-immunopositive neurons with TUNEL-negative nuclei.
G (positive control), the pyramidal cell layer of CA1
region in the gerbil hippocampus after transient ischemia. The neurons
possess numerous TUNEL-positive nuclei. Scale bars (shown in
B for A and B): 50 µm;
(shown in D for C and D),
20 µm; (shown in G for E-G), 100 µm.
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Figure 8.
Association of microglia with APP-accumulating
degenerating neurons. AxCAYAP (A, B) or AxCALacZ
(C, D) was injected into the dorsal hippocampus. Four
days later, cryosections were doubly labeled by fluorescent
immunohistochemistry with antibody AC-1 (A) or
anti--gal antibody (C) and the microglial
marker Griffonia lectin (B, D).
A-D, The hilus of the dentate gyrus.
Griffonia lectin-positive microglial cells
(arrowheads in B) are adjacent to the
APP-accumulating degenerating neuron (arrow in
A) but are absent from the vicinity of a
-gal-accumulating neuron (C, D). Scale bars (shown in
A for A-D): 50 µm.
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Several atrophic neurons in the CA3 region of AxCAYAP-infected
hippocampus were intensely labeled by toluidine blue staining. These
neurons had shrunken somata with irregular contours (Fig. 9A). Electron microscopic
examinations revealed that the atrophic neurons had electron-dense
perikarya and deformed nuclei with a slight chromatin condensation
(Fig. 9B). These neurons had moderately dilated endoplasmic
reticulum (Fig. 9B-E). Some degenerating neurons had
numerous clear vacuoles, multivesicular bodies, and dense bodies (Fig.
9D,E), suggesting that autophasic processes are operative in
these neurons (Nitatori et al., 1995). Moreover, microglial cells/phagocytes were detected in proximity to degenerating neurons (Fig. 9B) and a soma-like structure filled with numerous
autophagic vacuoles (Fig. 9E). A swollen presynaptic ending
(Fig. 9C) and a postsynaptic structure lacking the
presynaptic element (Fig. 9D) were identified, suggesting
that these synaptic abnormalities occur concomitantly with perikaryal
shrinkage. These pathological features were observed in the areas
containing APP-accumulating degenerating neurons (data not shown).
Thus, it is likely that intracellular accumulation of wild-type APP695
causes "shrinkage-type" neuronal death along with autophagic
processes and synaptic abnormalities, and that microglial cells are
involved in scavenging processes of these affected neurons.
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Figure 9.
Electron micrographs of degenerating CA3 neurons
of AxCAYAP-infected hippocampus. The hippocampal tissues were prepared
4 d after AxCAYAP infection and examined by electron microscopy. A, Toluidine blue staining of the CA3 region.
Arrowheads point to atrophic degenerating neurons.
B-E, Electron micrographs of CA3
neurons. C and D are enlarged images of
the areas shown by the arrow and
arrowhead in B, respectively. Note
abnormalities such as electron-dense cytoplasm (B,
E), numerous clear vacuoles (asterisk in
E), multivesicular bodies (arrowhead in
D), dense bodies (double arrowhead in
D), swollen presynaptic ending (arrow in
C), and postsynaptic density lacking presynaptic element
(arrow in D). Microglial cells are
adjacent to degenerating neurons (double arrows in
B, E). Note the microglial cell extending
the processes along the degenerated neuron (double
arrows and asterisk in E). Scale
bars: A, 50 µm; B, 5 µm;
C, 1 µm; D, 500 nm; E,
10 µm.
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DISCUSSION |
This study has shown that hypertonic mannitol for the direct viral
delivery into the hippocampal parenchyma markedly increases the number
of infected neurons. The disruption of BBB with hypertonic mannitol has
been previously applied to the adenovirus-mediated gene transfer via
intracarotid administration, but only glia-like cells were frequently
infected (Muldoon et al., 1995). After intracarotid mannitol
administration, capillary endothelial cells that form BBB may shrink,
and the tight junctions are temporarily opened, allowing the
recombinant adenovirus to enter the perivascular space. Similarly, the
direct adenovirus transfer into the brain parenchyma with hypertonic
mannitol may shrink non-neuronal cells that block the viral
accessibility to neurons. The retrograde transport of adenovirus has
been demonstrated previously by injecting the virus into the striatum
and detecting the labeled neurons in the substantia nigra (Ridoux et
al., 1994). Therefore, intrahippocampal neurons in this study may be
retrogradely infected, and hypertonic mannitol increases the viral
accessibility to the nerve terminals, resulting in the increased
retrograde transport to neuronal nuclei in which infected genes are
transcribed. Because adenovirus has potential nonspecific
cytotoxicities, we used the adenovirus vector carrying one of the
strongest promoters currently available (Niwa et al., 1991; Miyake et
al., 1996) to attain an equal effectiveness with less viral quantity.
Using this vector and the hyperosmotic modification in combination, we
have succeeded in demonstrating the APP-induced neurodegeneration.
Intraneuronal accumulations of APP in AD brain have been demonstrated
previously using various antibodies raised against different epitopes
of APP: a large number of hippocampal CA1 neurons in AD contain
abnormally dense APP C-terminal immunoreactive materials as compared
with controls (Benowitz et al., 1989). Hippocampal pyramidal neurons in
AD display an intense immunostaining with 10 different antibodies
against subsequences of APP (Cole et al., 1991). Pyramidal neurons in
hippocampal fields CA1-3 and entorhinal cortex in AD brain are
strongly stained with an antibody against APP N terminus (P2-1)
(Cummings et al., 1992). The areas containing these APP-accumulating
neurons are consistent with those showing the most intense
neuropathology in AD. However, it has been unclear whether
intracellular accumulation of APP is a cause of neurodegeneration seen
in AD brain. Using the adenovirus-mediated APP gene transfer, we were
able to demonstrate that neurons in vivo are vulnerable to
the intracellular accumulations of wild-type APP. The degenerating neurons had shrunken perikarya with deformed nuclei (Fig. 9). In the
nucleus basalis of Meynert complex in AD brain, cholinergic neurons
become smaller (Pearson et al., 1983), and the number of small
neurons in this region is significantly increased (Vogels et al.,
1990). Moreover, neuron shrinkage in the nucleus raphes dorsalis in AD
has also been suggested (Aletrino et al., 1992). Therefore, neuron
shrinkage may be a typical pathological feature of AD. Because
APP-accumulating pyramidal neurons in the hippocampus show severe
atrophy in AD brain (Benowitz et al., 1989), it is tempting to
speculate that intracellular accumulation of APP is responsible for
neuronal shrinkage seen in AD brain. Cell shrinkage is one of the
typical features of apoptosis (Kerr et al., 1987). We found that
nuclear DNA fragmentation, another feature of apoptosis, occurs in some
APP-accumulating neurons (Fig. 7). Previous studies have revealed that
nuclear DNA fragmentation is significantly increased in neurons in AD
brain (Su et al., 1994; Lassmann et al., 1995). Moreover, degenerating
APP-immunopositive neurons were often accompanied by reactive microglia
(Fig. 8), which are prevalent in AD brain (McGeer et al., 1993). These
findings together suggest that APP-accumulating neurons, at least in
part, undergo degeneration in a manner similar to apoptosis, and that a
specific type of neurodegeneration induced by APP occurs in AD
brain.
Transgenic mice overexpressing APP mutants such as APP
(Val717Phe) (Games et al., 1995) and APP695 (Lys670Asn/Met671Leu)
(Hsiao et al., 1996) have been reported to show neuropathological
changes accompanied by extracellular A depositions. However, no
overt neuronal loss is detected in the brain regions in which A is extensively deposited in APP (Val717Phe) transgenic mice (Irizarry et
al., 1997), suggesting that extracellular A deposits per se are
not toxic to neurons. The APP mutants used in the transgenic mice may
not be accumulated to toxic levels within neurons, whereas adenovirus-mediated overexpression of wild-type APP695 induces rapid
APP accumulations that exert toxic effects on neurons from inside. We
infer that such rapid accumulations of APP are attainable only by
strong overexpression systems such as those in vitro
(Hayashi et al., 1992; Yoshikawa et al., 1992) and in
vivo (present study). Molecular mechanisms underlying APP-induced
neurodegeneration remains to be elucidated. We have recently
demonstrated, by using the same APP695 cDNA-carrying adenovirus, that
overexpression of full-length APP in cultured rat hippocampal neurons
enhances the glutamate-induced rise of intracellular
Ca2+ concentration (Tominaga et al.,
1997). Such studies using the adenovirus-mediated APP gene transfer
system might provide valuable information about molecular mechanisms
whereby intracellular accumulation of wild-type APP causes
neurodegeneration.
| |
FOOTNOTES |
Received Oct. 3, 1997; revised Jan. 16, 1998; accepted Jan. 16, 1998.
This work was supported by Grants-in-Aid (07557332/08458253) from the
Ministry of Education, Science, and Culture of Japan (K.Y.). We thank
Dr. Haruo Okado for the adenovirus system, Dr. Takayuki Gotoh for
electron microscopy, and Dr. Tohru Nitatori for the TUNEL-positive
tissue preparation. We appreciate the generous gifts of antibodies from
Dr. Richard Mullen (A60), Dr. Tsuyoshi Ishii (Rb758), and Dr. William
Van Nostrand (P2-1).
Correspondence should be addressed to Dr. Kazuaki Yoshikawa, Division
of Regulation of Macromolecular Functions, Institute for Protein
Research, Osaka University, 3-2 Yamadaoka, Suita, Osaka 565, Japan.
| |
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Top
Abstract
Introduction
