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The Journal of Neuroscience, April 1, 2002, 22(7):2434-2442
Noradrenergic Depletion Potentiates  -Amyloid-Induced Cortical
Inflammation: Implications for Alzheimer's Disease
Michael T.
Heneka1,
Elena
Galea2,
Vitaliy
Gavriluyk2,
Lucia
Dumitrescu-Ozimek1,
JoAnna
Daeschner3,
M. Kerry
O'Banion3,
Guy
Weinberg2,
Thomas
Klockgether1, and
Douglas L.
Feinstein2
1 Department of Neurology, University of Bonn,
Germany 53127, 2 Department of Anesthesiology, University
of Illinois, Chicago, Illinois 60612, and 3 Department of
Neurobiology and Anatomy, University of Rochester Medical Center,
Rochester, New York 14642
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ABSTRACT |
Degeneration of locus ceruleus (LC) neurons and reduced levels of
norepinephrine (NE) in LC projection areas are well known features of
Alzheimer's disease (AD); however, the consequences of those losses
are not clear. Because inflammatory mediators contribute to AD
pathogenesis and because NE can suppress inflammatory gene expression,
we tested whether LC loss influenced the brain inflammatory gene
expression elicited by amyloid  (A). Adult rats were injected
with the selective neurotoxin
N-(2-chloroethyl)-N-ethyl-2 bromobenzylamine (DSP4) to induce LC death and subsequently injected in
the cortex with A (aggregated 1-42 peptide). DSP4 treatment potentiated the A-dependent induction of inflammatory nitric oxide
synthase (iNOS), interleukin (IL)-1, and IL-6 expression compared
with control animals. In contrast, the induction of cyclooxygenase-2 expression was not modified by DSP4 treatment. In control animals, injection of A induced iNOS primarily in microglial cells, whereas in DSP4-treated animals, iNOS was localized to neurons, as is observed
in AD brains. Injection of A increased IL-1 expression initially
in microglia and at later times in astrocytes, and expression levels
were greater in DSP4-treated animals than in controls. The potentiating
effects of DSP4 treatment on iNOS and IL-1 expression were
attenuated by coinjection with NE or the -adrenergic receptor agonist isoproterenol. These data demonstrate that LC loss and NE
depletion augment inflammatory responses to A and suggest that LC
loss in AD is permissive for increased inflammation and neuronal cell death.
Key words:
nitric oxide; amyloid; Alzheimer's disease; cytokines; locus ceruleus; interleukin
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INTRODUCTION |
The locus ceruleus (LC) is the main
subcortical site of norepinephrine (NE) synthesis and its precursor
enzymes. Noradrenergic axons arising from LC neurons project to several
cortical areas, including the hippocampus, entorhinal cortex, and
frontal cortex, where their axon terminals are in close contact with
neurons, astrocytes, and brain microvessels (Kalaria et al., 1989a ;
Paspalas and Papadopoulos, 1998). The LC-generated NE plays an
important role in selective attention, general arousal, and stress
reactions in response to challenging environmental situations (Foote et al., 1983; Levine et al., 1990), whereas experimentally induced loss of
LC neurons has been implicated in learning and behavior deficits
(Anlezark et al., 1973; Mason and Iversen, 1975; Harro et al., 1999).
Loss of LC neurons, degeneration of noradrenergic projections, and a
decrease in cortical NE levels are well described features of various
neurodegenerative diseases, including Alzheimer's disease (AD) and
Parkinson's disease. In addition, decreased LC neuronal counts are
significantly correlated with the numbers of amyloid (A)
plaques, neurofibrillary tangles, and the severity of dementia in AD
(Bondareff et al., 1987). However, despite many experimental and
neuropathological descriptions, the significance and role of LC cell
death for neurodegenerative disease remains unclear.
NE may have additional functions apart from its role as a classic
neurotransmitter. In astrocytes, NE blocked major histocompatibility complex class II (Frohman et al., 1988), tumor necrosis factor- (Hu
et al., 1991), and interleukin (IL)-1 (Willis and Nisen, 1995)
expression and inhibited expression of the inducible isoform of nitric
oxide synthase (iNOS) (Feinstein, 1998; Galea and Feinstein, 1999). NE
also inhibits inflammatory activation of microglial cells (Lee et al.,
1992; Loughlin et al., 1993; Chang and Liu, 2000). It has therefore
been suggested that NE plays a role as an endogenous anti-inflammatory
agent (Frohman et al., 1988; for review, see Feinstein et al.,
2001). In light of recent findings that neuroinflammatory events
contribute to AD pathology (Mrak et al., 1995; Stewart et al., 1997;
Akiyama et al., 2000), we reasoned that LC cell death and loss of
NE-mediated anti-inflammatory protection could exacerbate inflammatory
events contributing to the pathogenesis of AD. In this study, we
demonstrate that experimentally induced loss of LC neurons increases
the response of cortical LC projection areas to inflammatory changes
induced by A, including the appearance of neuronal iNOS expression,
which has been described in AD (Vodovotz et al., 1996; Lee et al.,
1999; Heneka et al., 2001). These results therefore establish a link
between classic AD pathology and neuroinflammatory events.
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MATERIALS AND METHODS |
Animals. Male Sprague Dawley rats (Charles River
Laboratories, Wilmington, MA) weighing 250-300 gm were housed in
groups of four under standard conditions at 22°C and a 12 hr
light/dark cycle with access to food and water ad
libitum.
Pretreatment and injection of immunostimulants. Rats
received two intraperitoneal injections (1 week apart) of either
N-(2-chloroethyl)-N-ethyl-2 bromobenzylamine
(DSP4; 50 µg/kg) dissolved in PBS or PBS alone (Fig.
1A). Four weeks after
the second treatment, the animals were anesthetized with pentobarbital
(50 mg/kg, i.p.), and placed in a stereotaxic frame (Stoelting, Wood
Dale, IL) on a heating blanket. Body temperature was maintained
at 37 ± 0.5°C for the time of surgery. After exposure of the
skull, holes were drilled bilaterally at the injection sites, and 2 µl of a mixture containing aggregated
A1-42 (0.5 µg/µl) was injected over a
period of 120 sec into each cortical hemisphere using a 2 µl Hamilton syringe at anteroposterior +2.0, lateral ±2.5, and ventral 3.0 mm
relative to the bregma (Paxinos et al., 1985). Controls received 2 µl
of PBS. At 6 hr, 1 d, 3 d, and 7 d after injections,
animals were killed by an overdose of pentobarbital, and brains were
removed. The cortical region of the right hemisphere was homogenized in Trizol reagent (Sigma, St. Louis, MO), and RNA was isolated according to recommended procedures. The left hemisphere was immersed in 20 ml of
fixative containing 10% formaldehyde, 10% acetic acid, and 80%
methanol (v/v/v) for 72 hr at room temperature and embedded in
paraffin. All experiments were performed in accordance with the
Declaration of Helsinki and the animal welfare guidelines and laws of
the United States and were approved by the local ethical committee for
animal experiments.
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Figure 1.
DSP4 induces NE depletion and LC cell loss. Rats
received two injections of DSP4 1 week apart (A),
followed 4 weeks later by intracortical injection of A or saline
(B). Serial sections from DSP4-treated rats
(C, E, G) and control rats (D, F,
H) were prepared 1 d later for immunocytochemistry
and stained for NE (C, D) or TH
(E-H). C, D, Sections from the
frontal cortex. E, F, Sections from the area of the LC.
G, H, Sections from the area of the substantia nigra.
Staining was performed on sections obtained from three animals in each
group; representative images are shown. Scale bars: C,
D, 25 µM; E-H, 50 µM.
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Processing of brains for immunohistochemistry.
Immunohistochemistry was performed as described previously (Heneka et
al., 1999a). Serial coronal sections of 8 µm thickness were cut with a Leitz (Wetzlar, Germany) microtome and mounted on
poly-L-lysine-coated slides. Slides were immersed
in 10 mM citrate buffer, pH 6.0, heated in a
microwave oven for four cycles of 5 min each to unmask antigen sites,
and then cooled and washed in PBS. For cyclooxygenase 2 (COX-2),
antigen retrieval was performed in 50 mM
Tris-HCl, pH 9.0, for 40 min at 190°C, followed by rinses in PBS and
10 min of incubation in cold methanol. Endogenous peroxidase activity was inhibited by rinsing slides in 0.1% hydrogen peroxide for 10 min.
Nonspecific binding was blocked by 10% normal goat serum in PBS for 1 hr at room temperature. After washing in PBS, sections were incubated
overnight at 4°C with the following primary antibodies (Abs): (1)
anti-iNOS monoclonal Ab (mAb) N32020 (1:200 dilution; Transduction
Laboratories, Lexington, KY), (2) anti-IL-1 mAb AF501N (1:200; R&D
Systems, Wiesbaden, Germany), (3) anti-glial fibrillary acidic protein
(GFAP) mAb MCA 363 (1:200; Serotec, Darmstadt, Germany), (4)
anti-ED1 mAb MCA 341 (1:100; Serotec), (5) anti-tyrosine
hydroxylase mAb (1:1000; DiaSorin, Stillwater, MN), (6)
anti-NE-glutaraldehyde conjugate polyclonal Ab (1:600, MoBiTec,
Göttingen, Germany); and (7) anti-COX-2 affinity-purified polyclonal Ab 160126 (1:1000; Cayman Chemical, Ann Arbor, MI). Sections
were washed extensively with PBS and subsequently incubated with
biotinylated or fluorescently labeled anti-rabbit or anti-mouse IgG
(1:200 dilution; Vector Laboratories, Burlingame, CA) for 30 min at
room temperature. Immunohistochemical localization was performed using
the avidin-biotin peroxidase complex method (ABC kit; Vector
Laboratories) with 3,3'-diaminobenzidine as chromogen or by confocal
laser microscopy.
Negative controls included use of nonspecific IgG instead of the
primary antibodies, preabsorption of primary antibodies with the
respective cognate peptides (150-200 µg of peptide per milliliter of
antibody working solution), and absence of immunoreactivity in
PBS-injected animals and noninjected contralateral hemispheres.
Confocal laser scanning microscopy. Double-labeled specimens
were analyzed with a confocal laser scanning microscope (Multiprobe 2001; Molecular Probes, Inc., Eugene, OR) equipped with an Ar/Kr laser
with balanced emission at 488, 568, and 647 nm. To achieve an optimal
signal-to-noise ratio for each fluorophore, sequential scanning with
568 and 488 nm was used. The digitalized images were then processed
with ImageSpace 3.10 software (Molecular Probes, Inc.) on a Silicon
Graphics (Mountain View, CA) power series 310GTX work station. Original
section series were subjected to Gaussian filtration to reduce noise
and enhance weakly but specifically labeled parts. Original and
filtered sections were projected on one plane using a maximum-intensity
algorithm and in some cases using depth-coding and surface-rendering algorithms.
Quantification of immunohistochemistry. Quantitative
analysis of cells that stained positively for iNOS, COX-2, GFAP, and IL-1 was performed on brain sections from four animals from each group. Antigens were detected in five sections having a defined distance relative to the level of cortical injection. The sections were
the middle section corresponding to the level of injection and four
sections taken at a distance of 35 and 70 µm rostral and caudal to
the injection site. The number of cells within the respective fields
was determined using a counting grid, and cells within the needle tract
were not counted.
RNA preparation and reverse transcription PCR. Total RNA was
extracted from brain samples using Trizol reagent according
to the manufacturer's instructions (Sigma), and reverse transcription (RT)-PCR was performed as described previously (Heneka et al., 2000).
The primers used were: iNOS forward, 5'-CTGCATGGAACAGTATAAGGCAAAC-3'; iNOS reverse, 5'-CAGACAGTTTCTGGTCGATGTCATGA-3'; IL-1 forward, 5'-GCTACCTATGTCTTGCCCGTGGAG-3'; IL-1 reverse,
5'-GTCCCGACCATTGCTGTTTCCTA-3'; COX-2 forward,
5'-TCCCGGATCCCCAAGGCACAAATA-3'; COX-2 reverse, 5'-TCAGACCCGGCACCAGACCAAAGA-3'; glyceraldehyde 3-phosphate
dehydrogenase (GDH) forward, 5'-ACGACAGTCCATGCCATCAC-3'; GDH
reverse, 5'-TCCACCACCCTGTTGCTGTA-3'; IL-6 forward,
5'-CTTGGGACTGATGTTGTTGA-3'; and IL-6 reverse, 5'-CTCTGAAT- GACTCTGGCTTTG-3'.
PCR conditions were 35 cycles of denaturation at 95°C for 30 sec,
annealing at 63°C for 45 sec, and extension at 72°C for 45 sec. For
iNOS, a 40 bp smaller internal iNOS standard was included in the PCR
mixture to facilitate quantification. PCR products were separated by
electrophoresis through 2% agarose containing 0.5 µg/ml ethidium
bromide and imaged using an AlphaInotech imaging system (Temecula, CA);
band intensities were determined using ImageJ software from the
National Institutes of Health (Bethesda, MD). For iNOS calculations,
the band intensities of the cDNA product were compared with those of
the internal standard. PCRs were performed on RNA prepared from three
different animals in each group; representative gels are shown.
Data analysis. Quantitative immunostaining and PCR data were
analyzed by one-way or two-way ANOVA with Bonferroni's multiple comparison post tests using Prism version 3.00 software (GraphPad Software, San Diego, CA).
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RESULTS |
Examination of brain sections prepared 5 weeks after DSP4
treatment showed a marked loss of LC neurons in DSP4 animals compared with animals injected with PBS as revealed by decreased tyrosine hydroxylase staining (Fig. 1E,F) and decreased
NE immunoreactivity in the cortex (Fig. 1C,D). DSP4 effects
were restricted to the LC, because tyrosine hydroxylase staining of
substantia nigral neurons was essentially the same in DSP4-treated as
in PBS-treated animals (Fig. 1G,H).
At 4 weeks after the second DSP4 treatment, rats were injected in the
frontal cortex with A or PBS (Fig. 1B). Injection
of A into control animals increased iNOS mRNA levels beginning 6 hr
after injection; iNOS mRNA reached maximal levels after 1 d, and
levels diminished but were still detectable after 3 d (Fig. 2). A similar pattern of iNOS mRNA
accumulation occurred after injection of A into DSP4-treated
animals; however, at all times, the levels attained were higher than
those in control animals (Fig. 2). Injection of PBS alone into either
control or DSP4 animals induced little or no detectable amounts of iNOS
mRNA. Semiquantitative competitive PCR indicated that compared with
injection with PBS, A increased iNOS mRNA levels approximately
ninefold in DSP4 animals after 6 hr, compared with only a 20% increase
in control animals (n = 3 each; p < 0.01); at 1 d, A increased levels ~36-fold in DSP4 animals
compared with ~24-fold in control animals (n = 3 each; p < 0.001) (Fig. 2B). The iNOS
mRNA levels decreased at day 3 and decreased further at day 7, at which
point iNOS mRNA was present at low but similar amounts in both groups
(p > 0.05; unpaired t test).
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Figure 2.
Inflammatory gene transcription in DSP4-treated
animals and controls. A, Total RNA was prepared from
cortices of DSP4-treated (+) and control ( ) rats at the indicated
times after intracortical injection of A and examined by RT-PCR for
iNOS, IL-1, COX-2, and GDH mRNAs. For iNOS, PCRs were performed in
the presence of 20 fg of a specific iNOS internal standard that yields
a PCR product 40 bp smaller than the band derived from the iNOS cDNA.
RT-PCRs were performed using RNA samples isolated from three animals in
each group; representative gels are shown. B,
Densitometric analysis of band intensities from three independent
experiments. Filled bars, DSP4 animals; open
bars, control animals. Data are the fold increase attributable
to A injection versus that attributable to saline injection
(mean ± SEM). *p < 0.05;
**p < 0.01; ***p < 0.001;
DSP4-treated animals versus controls.
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The levels of IL-1 mRNA were also increased in response to A
injection (Fig. 2). As observed for iNOS, IL-1 mRNA levels were
consistently higher in DSP4-treated animals compared with controls,
with maximal levels detected 1 d after injection (Fig. 2).
Densitometric analysis showed that after 1 d, A increased IL-1 mRNA levels 4.5-fold in DSP4 animals versus 1.4-fold in control
animals (n = 3 each; p < 0.001). As
was the case for iNOS, IL-1 mRNA levels decreased at 3 d and
decreased further at 7 d, although at this point the IL-1 mRNA
levels were still greater in DSP4-treated versus control animals
(p < 0.05; unpaired t test). Similarly, IL-6 mRNA levels were increased by A and increased to a
greater extent in DSP4-treated versus control animals. However, the
increase in IL-6 levels was transient, with a significant increase
observed only at 6 hr, the earliest time investigated. In contrast,
A injection showed little effect on the mRNA levels of either COX-2
(levels were slightly elevated by DSP4 at day 1 and slightly attenuated
at 3 d compared with control levels) or GDH (a small decrease was
observed in DSP4 animals vs controls on day 7).
At 1 d after A injection, iNOS protein was detected in two
different cell types. In control animals, iNOS was restricted primarily
to microglial cells (Fig. 3B),
whereas in DSP4-treated animals, iNOS was detected predominantly in
pyramidal cortical neurons (Fig. 3A). Injection of saline
into control or DSP4-treated animals did not lead to iNOS expression
(Fig. 3C), ruling out cross-reaction of the antibody used
with other NOS isoforms and consistent with our previous findings that
the antibody used detects a protein of ~130,000 Da in
immunostimulated but not control rat brain samples (Heneka et al.,
2000, 2001). Parenchymal iNOS-positive microglia were scattered
throughout the frontal cortex and occasionally observed in close
proximity to brain vessels (Fig. 3B, inset). Quantification revealed similar numbers of iNOS-positive microglial cells in control and DSP4-treated animals (Fig. 3J).
In contrast, the number of iNOS-immunopositive neurons was
significantly increased in the DSP4 group. Confocal laser microscopy of
an area near the injection site revealed costaining of the majority
(but not all, as indicated by arrows in Fig.
3F) of neurons for neuron-specific enolase (NSE) and
iNOS in DSP4 animals and costaining of microglial cells for ED1 and
iNOS in control animals (Fig. 3G-I).
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Figure 3.
Immunohistochemical localization of
iNOS. Serial sections were prepared from brains of DSP4-treated
(A, C) and control (B) rats at
1 d after injection of A (A, B) or saline
(C) and stained with antibody to iNOS;
immunoreactivity was detected by the DAB method. A, The
inset shows a positively stained cell with neuronal
morphology. B, The inset shows a
positively stained cell with microglial morphology. Cellular
identification of iNOS staining was obtained by confocal laser
microscopy of sections costained with antibodies to iNOS (D,
G) and either NSE to detect neurons
(E) or ED1 to detect microglial cells
(H). F, I, Overlapping
fluorescent signals; some NSE-positive, iNOS-negative neurons are
indicated by white arrows. Scale bars: A,
B, 50 µm; D-I, 25 µm. The images shown are
representative of sections obtained from three different animals in
each group. J, Staining was quantified by counting the
number of neurons (left) and microglia
(right) positively stained for iNOS in five serial
sections. The data are the mean ± SEM of four animals in each
group. *p < 0.05; **p < 0.005; ***p < 0.0005; DSP4-treated animals versus
controls.
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Immunocytochemical staining also revealed two cell types expressing
IL-1. At 1 d after A injection, IL-1 was detected
exclusively in microglial cells. Ramifications to oval or rounded
microglia cells were observed, suggesting different states of
activation (Fig. 4A,B).
Quantification revealed that DSP4-treated animals had a significantly
higher number of IL-1-immunopositive microglial cells than PBS
controls (Fig. 4L, left). IL-1 was not
detected in saline-injected animals (data not shown). Confocal
microscopy using ED1 for microglia detection revealed the morphological
nature of the IL-1-immunopositive cells (Fig. 4C-E). The
number of more highly arborized and ramified microglia appeared to be
higher in control versus DSP4-treated animals, suggesting a lesser
degree of microglial activation in controls.
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Figure 4.
Immunohistochemical localization of
IL-1. Serial sections were prepared from brains of DSP4-treated
(A) and control (B) rats at
1 d after injection of A and stained with an antibody to
IL-1; immunolabeling was detected by the DAB method. Limited
staining was observed in control sections, if the primary antibody was
omitted, or if the primary antibody was preincubated with a blocking
peptide. Cellular identification was obtained by confocal laser
microscopy of sections costained with antibodies to IL-1 (C,
F, I) and either ED1 to detect microglia at 1 d
(D) or GFAP to detect astrocytes at 7 d
(G, J). A-H are from sections
taken 35 µm from the injection site; I-K are from
sections take 70 µm from the injection site. E, H, K,
Overlapping fluorescent signals. Scale bars: A,
B, 50 µm; C-K, 25 µm. Images are
representative of sections obtained from three different animals in
each group. L, Staining was quantified by counting the
number of microglia (left, 1 d) and astrocytes
(right, 7 d) positively stained for iNOS in five
serial sections. The data are the mean ± SEM of four animals in
each group. *p < 0.05; **p < 0.005; ***p < 0.0005; DSP4-treated animals versus
controls.
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In contrast to the microglial localization observed at 1 d, after
7 d the IL-1 was detected almost exclusively in GFAP-positive astrocytes (Fig. 4). Although essentially all GFAP-positive cells proximal to the injection site were also IL-1-positive (Fig. 4F-H), distally located GFAP-positive cells
(Fig. 4J) were IL-1-negative (Fig.
4I,K), suggesting that not all astrocytes
undergoing gliosis are able to express IL-1 and ruling out the
possibility that activated astrocytes show a nonspecific high avidity
for the IL-1 antibody. As found for microglia at 24 hr, the
DSP4-treated animals showed a higher number of IL-1-positive
astrocytes at 7 d than did PBS controls (Fig.
4L, right).
IL-6 expression examined at 1 d after A injection was localized
primarily to pyramidal neurons in DSP4-treated (Fig.
5A) and to a much lesser
extent in control (Fig. 5B) animals (Fig. 5E,
right). IL-6-positive neurons were observed throughout the cortex but were significantly increased around the injection site. Similarly, cortical neurons were also the primary site of COX-2 expression (Fig. 5C,D), and no differences were observed in
the cellular localization between DSP4-treated and control rats.
Quantification of COX-2-immunopositive neurons revealed no significant
differences between DSP4-treated and control groups (Fig.
5C). In addition to neurons, COX-2 was also observed in
endothelial cells and to a minor extent in activated glial cells (data
not shown).
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Figure 5.
Immunohistochemical localization of IL-6 and
COX-2. Serial sections were prepared from brains of DSP4-treated
(A, C) and control (B, D) rats at 1 d after injection of A and were stained with antibodies to IL-6
(A, B) or COX-2 (C, D); immunolabeling
was detected by the DAB method. Scale bar, 50 µm. The images shown
are representative of sections obtained from three different animals in
each group. E, Staining was quantified by counting the
number of neurons positively stained for COX-2 (left) or
IL-6 (right) in five serial sections. The data are the
mean ± SEM of four animals in each group. *p < 0.05; DSP4-treated animals versus controls.
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Injection of A strongly increased the number of GFAP-positive cells
in the cortex (and in the nearby corpus callosum; data not shown)
compared with PBS injection at both time points investigated (24 hr and
7 d). In both brain regions, the DSP4-treated animals (Fig.
6B) showed a higher
number of GFAP-positive cells than did control rats (Fig.
6A), and this increase was statistically significant within the cortex (Fig. 6C).
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Figure 6.
Effect of DSP4 treatment on GFAP expression.
Serial sections were prepared from the frontal cortex of DSP4-treated
(A) and control (B) rats at
1 d after injection of A and stained with an antibody to GFAP;
immunolabeling was detected by the DAB method. Scale bar, 50 µm. The
images shown are representative of sections obtained from three
different animals in each group. C, Staining was
quantified by counting the average number of GFAP positively stained
astrocytes in five serial sections. The data are the mean ± SEM
of four animals in each group. *p < 0.05;
DSP4-treated animals versus controls.
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In DSP4-treated animals, coinjection with NE partially reversed
the A-dependent increase of both iNOS and IL-1 mRNA levels (Fig.
7A). As expected, injection of
A significantly increased iNOS mRNA levels (21.7 ± 0.5-fold vs
noninjected levels), and this effect was significantly reduced (to
8.6 ± 0.3-fold vs noninjected levels) by NE (n = 3 each; p < 0.0001) and by ~30% (to 15.2 ± 1.8-fold control levels) by coinjection of the -adrenergic receptor agonist isoproterenol (n = 3 each; p < 0.001). Similarly, A increased IL-1 mRNA levels (to 2.0 ± 0.1-fold of control levels), and those levels were significantly
(p < 0.001) reduced by ~40% by NE or by
isoproterenol. In contrast, coinjection of NE (or of isoproterenol; data not shown) had no effect on the increase of iNOS and IL-1 mRNA
levels after A injection into control animals (9.3 ± 0.2-fold and 1.3 ± 0.1-fold vs control levels for iNOS and IL-1,
respectively) (Fig. 7B). The mRNA levels of GDH (and of
COX-2; data not shown) were not affected by injection of NE or
isoproterenol. Coinjection of NE or of isoproterenol also reduced the
appearance of neurons that stained positive for iNOS after A
injection into DSP4-treated animals (Fig. 7C).
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Figure 7.
Effect of NE on DSP4 potentiation of iNOS and
IL-1 expression. Total RNA was prepared from frontal cortices of
DSP4-treated (left) and control (right)
rats at 1 d after injection of A (or saline, none) together
with a 100 nM concentration of NE
(+NE) or isoproterenol (+Iso).
Equal aliquots were converted to cDNA and assayed by competitive RT-PCR
for iNOS and RT-PCR for IL-1 and GDH. A,
Representative gel. B, Quantitative analysis performed
on band intensities obtained using ImageJ software. Values shown are
for mRNA levels relative to those measured in samples from
A-injected animals and are the mean ± SD of three animals in
each group. The 100% values correspond to fold increases of 21.7 ± 0.5 (iNOS in DSP4 rats), 9.3 ± 0.2 (iNOS in control rats),
2.0 ± 0.1 (IL-1 in DSP4 rats), and 1.3 ± 0.1 (IL-1 in
control rats) versus that caused by injection of PBS.
**p < 0.01; ***p < 0.0001 versus injection of A alone (one-way ANOVA; Bonferroni's multiple
comparison test). C-F, Immunocytochemical
staining for iNOS in representative cortical sections from DSP4-treated
rats at 1 d after injection of saline (C),
A (D), A plus NE (E),
or A plus Iso (F).
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DISCUSSION |
Our results for the first time establish a link
between two classic pathological hallmarks of AD, namely LC loss and
decreased noradrenergic innervation, and the recent understanding that
neuroinflammatory events contribute to neuronal dysfunction and cell
death in AD (Akiyama et al., 2000). Our findings suggest a causative
relationship between LC loss and the extent of projection area neuronal
damage incurred in response to inflammatory stimuli. Furthermore,
whereas iNOS expression in glial cells has been described in several
animal models of AD, to the best of our knowledge this is the first
example in which A induced neuronal iNOS expression, which is
observed in AD (Vodovotz et al., 1996; Lee et al., 1999).
Neuronal cell death of aminergic brainstem nuclei such as the LC and
the dorsal raphe nucleus is a well defined feature of AD pathology
(Mann et al., 1983; Wilcock et al., 1988; Forno, 1992). The LC is
located in the pontine tegmentum and serves as the main subcortical
site for the synthesis of NE (Freedman et al., 1975). Ascending
noradrenergic axons project to the hippocampus, to the frontal and
entorhinal cortex, and to a minor extent to various other brain
regions. Each LC neuron sustains a widely divergent axon that
innervates a large terminal field. Axon terminals are found in close
contact to neurons, astrocytes, and microglia, suggesting that NE acts
as a neuromodulator influencing a circumscribed microenvironment rather
than as a classic neurotransmitter (Seguela et al., 1990; German et
al., 1992).
In AD, the central portion of the LC, which projects predominantly to
the hippocampus, frontal cortex, and temporal cortex (areas that are
usually severely affected by senile plaque and neurofibrillary tangle
formation), shows the most extensive loss of cells (Marcyniuk et al.,
1986). LC loss and the degeneration of ascending noradrenergic axons
leads to decreased NE levels in respective projection areas (Adolfsson
et al., 1979; Iversen et al., 1983), whereas adrenergic receptors are
upregulated in response to the noradrenergic deafferentation (Kalaria
et al., 1989b). Since the initial neuropathological descriptions of LC loss, several studies have demonstrated a significant correlation between LC cell death or decreased cortical NE levels and the severity
and duration of dementia in AD (Mann et al., 1982; Bondareff et al.,
1987; German et al., 1992); however, the basis for this correlation is
not clear. For example, it has been suggested that in AD, LC
degeneration causes a denervation microangiopathy characterized by
thickened capillary walls that compromise normal blood-brain barrier
function, including nutrition of the brain parenchyma, which could
contribute to generalized neuronal dysfunction (Scheibel et al., 1987).
Alternatively, numerous reports indicate that NE can regulate
inflammatory gene expression in brain cells through modulation of the
intracellular second messenger cAMP. Our own studies (Feinstein, 1998)
and those of others (Galea and Feinstein, 1999) show that NE inhibits
iNOS expression in astrocytes, mediated by activation of -adrenergic
receptors and increases in cAMP.
To address the hypothesis that there is a causative link between LC
loss and reduced NE content and inflammatory events in AD, we used the
selective neurotoxin DSP4 (Fritschy and Grzanna, 1991) to create
chemical lesions in LC neurons and reduce cortical NE levels. DSP4 has
been demonstrated previously to influence neurodegenerative processes,
including those induced by N-methyl-4-phenyl 1,2,3,6-tetrahydropyridine (Mavridis et al., 1991) and by cerebral ischemia (Nishino et al., 1991). In our studies, we used a lower concentration of DSP4 than commonly used (we injected 50 µg/kg twice
vs a single injection of 10-50 mg/kg) and waited 4 weeks before
additional experimentation. This treatment caused selective degeneration of noradrenergic projections and cell death of LC neurons,
whereas in the same animals, we did not observe any loss of substantia
nigra neurons. Thus, in the present study, DSP4 treatment provides a
model reflecting the impaired state of the noradrenergic system in AD.
Our data confirm that, as observed previously (Weldon et al., 1998),
intracortical injection of aggregated A induces an inflammatory response involving microglial expression of iNOS and IL-1 and astrogliosis represented by increased GFAP expression. These results demonstrate that under normal physiological conditions, both neurons and glia have the capacity to respond to immunostimulation by A,
although it is not known whether these responses are a direct result of
cell activation by A or are indirectly attributable to A-induced
release of other proinflammatory molecules. These responses involved a
limited number of cells, and increased mRNA expression returned to
basal levels within 3 d after A injection. The restoration to
basal levels suggests that in the normal animal, autoregulatory
mechanisms are invoked to reduce ongoing inflammation.
In contrast to control animals, cortical inflammatory responses in
DSP4-treated animals occurred sooner, were more robust, and were of
prolonged duration. Our data show that after A injection, the
IL-1 mRNA was transiently expressed, with maximal levels observed
after 1 d and much reduced levels observed at days 3 and 7 (Fig.
2). Immunocytochemical staining (Fig. 4) done at day 1 revealed IL-1
expression primarily in microglia, whereas at day 7 we observed strong
astroglial staining in areas near the site of A injection. Because
there are much lower levels of IL-1 mRNA at day 7 compared with day
1 or day 3, robust astroglial expression at day 7 might be caused
by IL-1 protein that was translated from mRNA present at
earlier times. These data also suggest that astrogliosis alone is not
sufficient to induce IL-1 expression, because astroglial IL-1 was
not detected at day 1 despite greatly increased GFAP levels (Fig. 6),
and because we detected GFAP-positive, IL-1-negative cells more
distal to the injection site (Fig. 4J,K). The
absence of astroglial staining at day 7 using other antibodies (COX-2
or nonspecific IgG; data not shown) also suggests that nonspecific
antibody binding to activated astrocytes does not account for the
observed IL-1 staining. Although microglia have been described as
the prominent IL-1-producing cell type in the brain (Sheng et al.,
2001), there is increasing evidence that astrocytes can produce IL-1
both in vitro (Hu and Van Eldik, 1999; Akama and Van Eldik,
2000) and in vivo (Lee et al., 2000; Mehlhorn et al., 2000;
Apelt and Schliebs, 2001). In one study using Tg2576 transgenic mice,
which overexpress the Swedish amyloid precursor protein double
mutation, IL-1 was detected in astrocytes near both fibrillary and
diffuse amyloid plaques, whereas microglial IL-1 was detected only
around the fibrillary plaques (Apelt and Schliebs, 2001). In contrast,
in other studies with these mice, only microglial IL-1 was detected
(Benzing et al., 1999; Sigurdsson et al., 2001).
DSP4 treatment caused an increase in A-dependent iNOS expression
that was detected at both the mRNA and protein levels. The expression
of iNOS in control animals was observed primarily in activated
perivascular and parenchymal microglial cells, whereas in DSP4-treated
animals, iNOS was detected primarily in neurons. This is in contrast to
the effects of DSP4 on IL-1 expression, where the expressing cells
remained the same although the overall expression increased. This
suggests that DSP4 treatment does not lower the threshold or increase
the capacity of microglial cells to express iNOS but instead lowers the
threshold and/or increases the levels of stimulatory factors needed to
induce neuronal expression. Although iNOS expression in
neurodegenerative disease has been described previously (Licinio et
al., 1999), it is only in AD that neuronal rather than glial or
endothelial expression has been observed (Vodovotz et al., 1996; Lee et
al., 1999). Treatment of animals with DSP4 may therefore provide a
model to further examine the regulation and consequences of neuronal
iNOS in AD.
The inability of A to induce neuronal iNOS under normal conditions
could reflect a basal refractory state of these neurons that is
imparted to them by the normal NE levels. Findings that intraparenchymal injection of lipopolysaccharide and cytokines into the
cerebellum induces iNOS expression in cerebellar granule neurons
(Heneka et al., 1999a), whereas similar injections into the cortex or
striatum induce only glial iNOS (Heneka et al., 1999b), are consistent
with the idea that cortical neurons are intrinsically resistant to
inflammatory activation. Diminished NE protection could therefore
decrease the threshold necessary for neuronal inflammatory gene
transcription in response to A and cytokines. Alternatively, it is
also possible that neuronal iNOS expression is attributable to the
greater and prolonged microglial (and eventual astroglial) IL-1
expression that occurs in the DSP4-treated animals. Finally, DSP4
treatment may facilitate the expression and accumulation of additional
cytokines, which may be required for neuronal iNOS expression.
It has been suggested that LC dysfunction occurs early in AD and
precedes a retrograde degenerative process that results in a gradual
loss of cortical-projecting LC neurons (German et al., 1992). This
dysfunction and a subsequent decrease of NE in cortical projection
areas may promote proinflammatory events evoked by A deposition and
plaque formation, thereby initiating or contributing to the above
retrograde LC degeneration. We therefore hypothesize that neuronal LC
loss and neuropathological and inflammatory changes are members of a
vicious self-maintaining and self-stimulating cycle. Future studies
will further characterize this cycle and evaluate at which point and by
what treatment a beneficial interruption of this cycle can be achieved.
| |
FOOTNOTES |
Received Nov. 26, 2001; revised Jan. 3, 2002; accepted Jan. 7, 2002.
This study was supported in part by grants from the Deutsche
Forschungsgemeinschaft (SFB 400, A8) to M.T.H. and T.K., a Gerok grant
from Bonfor to M.T.H., and National Institutes of Health Grants NS31556
to D.L.F. and NS33553 to M.K.O. We thank H.-U. Klatt and A. Sharp for
excellent technical assistance.
Correspondence should be addressed to Douglas L. Feinstein, Department
of Anesthesiology, University of Illinois, 1819 West Polk Street, MC
519/Room 544, Chicago, IL 60612. E-mail: dlfeins{at}uic.edu.
| |
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