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The Journal of Neuroscience, November 1, 2001, 21(21):8370-8377
The Curry Spice Curcumin Reduces Oxidative Damage and Amyloid
Pathology in an Alzheimer Transgenic Mouse
Giselle P.
Lim1, 3,
Teresa
Chu1, 3,
Fusheng
Yang1, 3,
Walter
Beech1, 3,
Sally A.
Frautschy1, 2, 3, and
Greg M.
Cole1, 2, 3
Departments of 1 Medicine and 2 Neurology,
University of California, Los Angeles, Los Angeles, California 90095, and 3 Greater Los Angeles Veterans Affairs Healthcare
System, Geriatric Research, Education and Clinical Center,
Sepulveda, California 91343
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ABSTRACT |
Inflammation in Alzheimer's disease (AD) patients is characterized
by increased cytokines and activated microglia. Epidemiological studies
suggest reduced AD risk associates with long-term use of nonsteroidal
anti-inflammatory drugs (NSAIDs). Whereas chronic ibuprofen suppressed
inflammation and plaque-related pathology in an Alzheimer transgenic
APPSw mouse model (Tg2576), excessive use of NSAIDs targeting
cyclooxygenase I can cause gastrointestinal, liver, and renal toxicity.
One alternative NSAID is curcumin, derived from the curry spice
turmeric. Curcumin has an extensive history as a food additive and
herbal medicine in India and is also a potent polyphenolic antioxidant.
To evaluate whether it could affect Alzheimer-like pathology in the
APPSw mice, we tested a low (160 ppm) and a high dose of dietary
curcumin (5000 ppm) on inflammation, oxidative damage, and plaque
pathology. Low and high doses of curcumin significantly lowered
oxidized proteins and interleukin-1 , a proinflammatory cytokine
elevated in the brains of these mice. With low-dose but not high-dose
curcumin treatment, the astrocytic marker GFAP was reduced, and
insoluble -amyloid (A), soluble A, and plaque burden
were significantly decreased by 43-50%. However, levels of amyloid
precursor (APP) in the membrane fraction were not reduced. Microgliosis
was also suppressed in neuronal layers but not adjacent to plaques. In view of its efficacy and apparent low toxicity, this Indian spice component shows promise for the prevention of Alzheimer's disease.
Key words:
Alzheimer's disease; inflammation; oxidative damage; anti-oxidant; microglia; plaque; interleukin-1; Tg2576; APPswedish
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INTRODUCTION |
Alzheimer's disease (AD) involves a
chronic CNS inflammatory response that is associated with both head
injury and -amyloid (A) pathology (Rogers et al., 1996 ).
In populations with prolonged use of nonsteroidal anti-inflammatory
drugs (NSAIDs), including the common over-the-counter medication
ibuprofen, the risk for AD is significantly reduced (Breitner et al.,
1995; Stewart et al., 1997). Consistent with this epidemiological
association, chronic ibuprofen treatment significantly suppressed
inflammation and the development of -amyloid pathology in an animal
model for Alzheimer's disease, the Tg2576 APPSw transgenic mouse (Lim et al., 2000). However, a principal limitation precluding widespread NSAID use for prevention of AD is gastrointestinal and occasional liver
and kidney toxicity caused by inhibiting cyclooxygenase I (Bjorkman,
1998; Tomoda et al., 1998; Cappell and Schein, 2000; McGettigan and
Henry, 2000; Sung et al., 2000). Side effect issues could be overcome
using alternative anti-inflammatory drugs directed against different
inflammatory targets.
Significant oxidative damage occurs in AD (Smith et al., 1991;
Friedlich and Butcher, 1994; Smith et al., 1997; Montine et al., 1999). Because antioxidants can protect neurons from -amyloid toxicity in vitro (Behl et al., 1994; Mattson and Goodman,
1995), a clinical trial was performed to test the ability of vitamin E to slow down the progression of AD (Sano et al., 1997).
However, the limited success of this high-dose  -tocopherol trial has
generated interest in other antioxidants because -tocopherol (unlike
 -tocopherol) is a poor scavenger of the nitric oxide (NO)-based free
radicals produced during inflammation (Christen et al., 1997) and
elevated in AD (Adams et al., 1991; Smith et al., 1997). One phenolic
antioxidant alternative is curcumin, a yellow curry spice derived from
turmeric. This spice is used as a food preservative and herbal medicine in India (Kelloff et al., 1991; Kelloff et al., 2000), where the prevalence of AD in patients between 70 and 79 years of age is 4.4-fold
less than that of the United States (Ganguli et al., 2000). Curcumin is
several times more potent than vitamin E as a free radical scavenger
(Zhao et al., 1989), protects the brain from lipid peroxidation
(Martin-Aragon et al., 1997), and scavenges NO-based radicals
(Sreejayan and Rao, 1997). Based on these considerations, we tested
curcumin for its ability to inhibit the combined inflammatory and
oxidative damage that occur as a response to amyloid in the transgenic
mouse model APPSw. This model, which carries a human familial AD gene
(amyloid precursor protein with the "Swedish" double mutation)
(Hsiao et al., 1996), displays age-related neuritic plaque pathology, a
quantifiable inflammatory response (Frautschy et al., 1998), oxidative
damage (Perry and Smith, 1997; Pappolla et al., 1998; Smith et al.,
1998), and age-related memory deficits linked to defective long-term
potentiation (LTP) (Chapman et al., 1999).
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MATERIALS AND METHODS |
Animals. Ten-month-old male and female APPSw Tg+ and
Tg mice from 12 litters were randomly split between treatment groups. Tg+ mice were fed either chow (PMI Feeds Inc., St. Louis, MO) containing a low dose of curcumin (160 ppm; n = 9;
Sigma, St. Louis, MO), a high dose of curcumin (5000 ppm;
n = 6), or no drug (n = 8) for 6 months
before being killed. Tg littermates were fed chow containing
no drug (n = 5). At the time of death, neither the
weights nor the ages of the mice were significantly different, and
there were no indications of diet-related toxicities. Mice were
perfused with 0.9% normal saline, followed by HEPES buffer, pH 7.2, containing 5 mg/ml each leupeptin and aprotinin and 2 mg/ml pepstatin
A. Brain regions were dissected from one hemisphere using mouse brain
atlas coordinates (Franklin and Paxinos, 1997) as reported previously
(Lim et al., 2000). Thalamic, cortical, and hippocampal regions, as
well as entorhinal cortex and piriform cortex-amygdala sections, were
dissected out and snap frozen in liquid nitrogen. Biochemical
measurements were performed in the hippocampus, entorhinal cortex,
piriform cortex-amygdala, and residual cortex (cortex region without
frontal, entorhinal, or piriform areas).
Tissue preparation. Tissue samples were processed as
described previously (Lim et al., 2000). Briefly, samples were
homogenized in 10 vol of TBS containing a cocktail of protease
inhibitors (20 µg/ml each pepstatin A, aprotinin, phosphoramidon, and
leupeptin, 0.5 mM PMSF, and 1 mM EGTA). Samples were sonicated briefly (two times for 10 sec) and centrifuged at 100,000 × g for
20 min at 4°C. The soluble fraction (supernatant) was used for
interleukin-1 (IL-1) or soluble A ELISAs, whereas the
TBS-insoluble pellet was sonicated in 10 vol of 2% SDS. The resulting
homogenate was centrifuged at 100,000 × g for 20 min
at 20°C. The SDS-soluble fraction was used for Western analysis of
GFAP and APP but not for A ELISA. To analyze insoluble A, the
SDS-insoluble pellet was solubilized and sonicated in 70% formic acid.
The resulting extract was neutralized with 0.25 M
Tris containing 30% acetonitrile and 5 M NaOH.
Sandwich ELISA for A. Our sandwich ELISA for total A
has been described previously (Lim et al., 2000). Briefly, the assay uses monoclonal 4G8 against A17-24 (Senentek, Napa, CA) as the capture antibody (3 µg/ml), biotinylated 10G4 against A1-15 as the detecting antibody, and a reporter system using
streptavidin-alkaline phosphatase and AttoPhos (JBL Scientific Inc.,
San Luis Obispo, CA) as the substrate (excitation, 450 nm; emission,
580 nm).
Sandwich ELISA for IL-1. This assay using polyclonal
antibody against mouse IL-1 (Endogen, Woburn, MA) for capture and
monoclonal anti-mouse IL1- (Endogen) for detection can measure
IL- down to 0.5 pg under most conditions (Lim et al., 2000).
Measurement of oxidized proteins. Amounts of oxidized
proteins containing carbonyl groups were measured using an Oxyblot kit (Intergen, Purchase, NY). Briefly, 10 µg of protein from the SDS extract were reacted with 1× dinitrophenylhydrazine (DNPH) for 15-30
min, followed by neutralization with a solution containing glycerol and
-mercaptoethanol. These samples were electrophoresed on a 10%
Tris-glycine gel, transferred, and blocked. The blot was incubated
overnight with a rabbit anti-DNPH antibody (1:150) at 4°C,
followed by incubation in goat anti-rabbit (1:300) for 1 hr at room
temperature. Bands were visualized using chemiluminescent techniques
with nonsaturating exposures and quantified.
Immunoblots for GFAP and APP. Levels of GFAP and APP (rabbit
polyclonal 681-695; Kang sequence) were determined on immunoblots containing 40 µg of SDS-soluble brain homogenate. Blots were
performed as described previously (Lim et al., 2000).
Immunostaining and image analysis. Immunohistochemistry and
image analysis of anti-amyloid-stained deposits and microglia was
performed on coronal brain sections from Tg+ untreated and Tg+ animals
treated with low-dose curcumin as described previously (Lim et al.,
2000). Tissue from the high-dose curcumin (HD curcumin) group was taken
for electrophysiology and not available. Briefly, 10 µm hemibrain
cryostat sections cut from the posterior pole to the anterior margin of
the hippocampus were incubated overnight at 4°C (1:100) in
"DAE" polyclonal antibody (anti-A1-13) made against
synthetic peptides A1-13 or antibody against phosphotyrosine (PT),
which serves as a rodent microglia marker (Frautschy et al., 1998).
Briefly, antigen retrieval was accomplished by incubating sections in
an unmasking solution (Vector Laboratories, Burlingame, CA) for 30 sec
in a pressure cooker. Sections were allowed to cool down to room
temperature before they were washed with TBS, and endogenous peroxidase
was quenched with 0.3% hydrogen peroxide for 15 min. After blocking
with normal serum, sections were incubated with anti-PT (1:400) at
37°C for 40 min. Slides were incubated in biotinylated goat
anti-rabbit antibodies for DAE staining (1:1000) or biotinylated goat
anti-mouse antibodies for PT staining (1:1000), followed by ABC
reagent, each for 30 min at 37°C. Sections were developed with metal
enhanced DAB (Pierce, Rockford, IL). On adjacent sections, DAE yielded
similar results to monoclonal antibodies A17-24 (4G8) or A37-42
(2G9, 7A3). However, the rabbit polyclonal DAE was used for image
analysis because it lacked the occasional vascular artifacts present
when mouse monoclonals are used on mouse tissue.
Image analysis of DAE was performed on two coronal sections per brain.
All images were acquired from an Olympus Optical (Tokyo, Japan)
Vanox-T microscope with an Optronix Engineering LX-450A CCD
video system. The video signal was routed into a Macintosh computer via
a Scion Corp. (Frederick, MD) AG-5 averaging frame grabber, and these
digitized images were analyzed with NIH Image public domain software.
Custom Pascal macro subroutines were written to calculate various
parameters of A immunostaining, which included number of plaques,
mean diameter, mean area, mean percentage area, and total area of
plaques. Plaque burden was defined as percentage of total hippocampal
and cortical area stained for A, excluding identifiable vascular
labeling. Individual plaque areas were assessed at 20× optical
magnification, an analysis requiring acquisition of several microscopic
fields. Total brain region areas were determined with 1×
magnification. Then plaque areas per hemibrain section were totaled,
and this sum area was divided by total hippocampal and cortical area of
the relevant hemibrain section.
Image analysis was also used to obtain percentage of PT (DAB-labeled)
area in rings of one and two plaque radii around anti-A-vector blue-labeled plaques and in cortical and hippocampal neuronal layers
(layers 1-6 of parietal, occipital, and temporal cortex; layers 1-3
of entorhinal cortex and hippocampal stratum oriens and lacunosum,
outer and inner molecular layers, and hilus of the dentate).
Statistical analyses. A two-factor ANOVA (treatment × region or transgene × region) was performed to analyze
differences in levels of IL-1, GFAP, soluble and insoluble A,
carbonyl proteins (Oxyblot), and image analysis data. For evaluating
microglial response to plaques in the ring analysis, a 2 × 2 ANOVA of microglial staining (percentage area) was performed, with
treatment and ring being analyzed. Ring 1 labeling measures microglial
staining within plaques, whereas ring 2 labeling measures microglial
staining in the immediate vicinity but outside of plaques. A "ring
effect" would signify that microglial staining is dependent on
proximity to plaques. A treatment by ring interaction would imply that
treatment effect may be dependent on ring. Post hoc
comparisons between regions were performed using Fisher's PLSD.
Bartlett's test for homogeneity of variances was also performed to
determine whether variances were equal. Some analyses required
logarithmic or square root transformations to establish homogeneity.
p < 0.05 was considered significant.
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RESULTS |
Curcumin decreases IL-1 levels in Tg+ mice
Accumulating evidence implicates interleukin-1 in AD pathogenesis
(Sheng et al., 1996; Griffin et al., 1998, 2000). We chose to assay
interleukin-1 because it is not only involved in AD and elevated in
Tg2576 (Lim et al., 2000) but also because age-related elevations of
IL-1 in rodents have been implicated in age-related memory loss and
defective LTP (Murray and Lynch, 1998). Levels of IL-1 were measured
from the soluble fraction of three diet groups: Tg+ untreated, Tg+
low-dose curcumin, and Tg+ HD curcumin. Measurements were made in four
brain regions (hippocampus, entorhinal cortex, piriform cortex, and
residual cortex) and analyzed by two-factor ANOVA (diet × region). Our previous studies revealed a significant transgene effect
in Tg+ mice compared with Tg mice, in which IL-1 levels were
elevated 2.4-6.7-fold in various regions of the brain (Lim et al.,
2000). In the current study, two-way ANOVA showed a significant
treatment effect with low-dose curcumin, decreasing IL-1 expression
by 61.8% (F(1,57) = 19.6;
p < 0.0001) (Fig.
1A), with a significant
treatment-region interaction. In addition, high doses of curcumin also
significantly lowered IL-1 levels in Tg+ mice by 57%
(F(1,48) = 31.8; p < 0.0001) (Fig. 1B). Therefore, both low and high doses
of curcumin can decrease levels of IL-1 in Tg+ mice.
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Figure 1.
Effect of curcumin on IL-1 on APPSw brains.
A, Effect of low-dose curcumin on IL-1. Protein
levels were measured in TBS-extracted supernatant from Tg+ mice fed
low-dose curcumin diet and untreated Tg+ mice. Levels of IL-1 were
significantly decreased by 61.8%. in curcumin-treated animals.
*p < 0.05. B, Effect of high-dose
curcumin on IL-1. Protein levels were measured in TBS-extracted
supernatant from Tg+ mice fed a high-dose curcumin diet and untreated
Tg+ mice. Two-way ANOVA revealed a 57% reduction in IL-1 levels in
Tg+ mice receiving a high dose of curcumin compared with untreated
animals. ***p < 0.001.
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Immunoblot analysis was used to determine whether curcumin could lower
levels of GFAP, an astrocyte marker that is often elevated in
inflammatory conditions and is increased in amyloid-forming APP
transgenic mice (Irizarry et al., 1997). Levels of GFAP were significantly increased by 20% in APPSw mice (Lim et al., 2000). Two-way ANOVA demonstrated a significant treatment effect with low-dose
curcumin, in which levels were decreased by 16.5%
(F(1,58) = 4.8; p = 0.03). No significant treatment effects were observed with high-dose
curcumin (data not shown).
Microglial activation was estimated by measuring the percentage of
PT-stained area on cryostat sections in untreated and curcumin-treated (low-dose) animals. Two-way ANOVA (diet × region) demonstrated a
diet effect in cortical and hippocampal layers in treated animals, in
which percentage of PT-stained area was significantly reduced by 31%
(p < 0.0001) (Fig.
2A,B).
Curcumin had the greatest impact on the outer molecular layer of the
hippocampus and layer two of the cortex (data not shown). As shown in
Figure 2, C and D, curcumin did not significantly
reduce microglial staining within plaques (ring 1) and even
significantly increased plaque-associated PT immunolabeling immediately
outside of plaques (ring 2).
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Figure 2.
Reductions in percentage of stained microglia in
response to dietary curcumin (160 ppm) were observed in neuronal layers
in every region examined except the hilus of the hippocampus
(A). Layers 1 of the cortex and the stratum
oriens of the hippocampus were minimally affected, whereas the most
robust reductions were observed in layer 2 of the cortex (40%
reduction) and the outer molecular layer (OML) of the
dentate gyrus (53% reduction). An example of the PT staining
quantified in the OML is shown in B. D,
Percentage of PT staining was quantified within plaques (ring
1) and associated within 1 plaque radius (ring
2). Whether curcumin altered the association of microglia with
plaques was analyzed by analysis of the staining within these rings,
using a 2 × 2 ANOVA (treatment diet × ring) of microglial
staining (percentage area). A ring effect signifies that
microglial staining is dependent on proximity to the plaque. The
treatment × ring interaction signifies that curcumin treatment
effects depend on the ring analyzed. As shown in C,
microglial PT staining was not reduced within plaques (ring 1) but was
even increased in ring 2 around plaques in curcumin-treated animals.
IML, Inner molecular layer.
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Oxidative damage is reduced in curcumin-treated mice
Oxidative damage was assessed in Tg untreated, Tg+ untreated,
and Tg+ HD curcumin groups using Western blot analysis, in which
carbonyl groups on oxidized proteins were derivitized with DNPH and
detected using an anti-DNP antibody. A representative example of
an Oxyblot is shown in Figure 3. Two-way
ANOVA (transgene × region) revealed a significant transgene
effect in oxidized protein levels, which were increased 10.7-fold in
Tg+ untreated mice (F(1,36) = 47.6;
p < 0.0001) (Fig. 3B), consistent with
previous reports of oxidative damage in APPSw mice. A combined regional analysis of all four brain regions revealed that animals treated with
high doses of curcumin had a significantly lower level of oxidized
proteins (46.3%) compared with untreated animals
(F(1,47) = 6.3; p = 0.01) (Fig. 3C). Oxidative damage was measured in two brain
regions (residual cortex and piriform cortex) of animals treated with
the low dose of curcumin. Two-way ANOVA revealed a significant
treatment effect with low-dose curcumin, in which oxidized protein
levels were reduced 61.5% in treated animals (F(1,31) = 7.31; p = 0.01) (Fig. 3D). Therefore, both low and high doses of
curcumin significantly decreased levels of oxidized proteins in the
APPSw mice.
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Figure 3.
Measurement of oxidized proteins in APPSw mice.
A, Representative example of Oxyblot using 10 µg of
protein from Tg untreated and Tg+ untreated entorhinal cortex
samples. B, Transgene effect on oxidized proteins, as
measured by Oxyblot, of SDS-extracted supernatant from hippocampus and
entorhinal cortex of Tg untreated (n = 9) and Tg+
untreated (n = 6). Two-way ANOVA showed a highly
significant transgene effect, in which the levels of oxidized proteins
were 12-fold higher in Tg+ animals compared with Tg animals.
***p < 0.001. C, High-dose curcumin
effect. Levels of oxidized proteins in oxyblots of SDS-extracted
supernatant from hippocampal, entorhinal, and piriform cortices of Tg+
untreated (n = 6) and Tg+ high-dose curcumin
(n = 8). Two-way ANOVA showed that levels of
oxidized proteins were 46% lower in mice fed a diet containing a
high-dose of curcumin (HD curcumin).
*p < 0.05. D, Low-dose curcumin
effect. Amounts of oxidized proteins in residual cortex and piriform
cortex of Tg+ untreated and Tg+ curcumin-treated animals. Two-way ANOVA
revealed a significant treatment effect. *p < 0.05. OD, Optical density.
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Low doses of curcumin reduce TBS-soluble A and SDS-insoluble
A (amyloid)
Previous studies have shown that a chronic dose of ibuprofen
significantly reduces insoluble and soluble A in APPSw mice (Lim et
al., 2000). We tested whether this same effect was seen in
curcumin-treated animals. Levels of SDS-insoluble A were
measured by ELISA in entorhinal cortex, hippocampus, and residual
cortex regions. Two-way ANOVA (treatment × region) revealed a
significant reduction in insoluble A
(F(1,36) = 10.97; p = 0.002), in which amounts were lowered by 39.2% (Fig.
4A). There was also a
significant region-dependent effect
(F(2,36) = 13.7; p < 0.0001), in which insoluble A levels were decreased in all regions
except in residual cortex (data not shown). High doses of curcumin, on
the other hand, did not alter the level of insoluble A in the brains
of treated mice (data not shown).
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Figure 4.
Effect of low-dose curcumin on
SDS-insoluble A and plaque pathology. A, Formic acid
extracted (SDS-insoluble) A as measured by sandwich ELISA. A was
measured in the three regions of the brain: hippocampus, entorhinal
cortices, and residual cortex. A two-way ANOVA (treatment × region) showed significant treatment effects in insoluble A levels
(***p < 0.001). Homogeneity of variance was
obtained using a natural log transformation of square root transformed
values. B, Plaque burden (percentage of hippocampal and
cortical area stained with amyloid) in Tg+ untreated and Tg+ low-dose
curcumin mice. Image analysis was performed on amyloid-positive
structures (DAE-positive) in hemibrain cryostat sections. Two-way
ANOVA revealed a significant 43% reduction in plaque burden in
curcumin-treated animals (*p = 0.03).
C, Soluble A in Tg+ untreated and Tg+ low-dose
curcumin mice as measured by sandwich ELISA. A levels were measured
in hippocampus, entorhinal cortex, piriform cortex, and residual cortex
regions. Two-way ANOVA (treatment - region) showed significant
treatment effects in decreasing the levels of soluble A
(*p < 0.05).
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Two-way ANOVA (treatment × region) revealed a significant
reduction in the level of soluble A in animals treated with
low-dose curcumin (F(1,61) = 4.02;
p = 0.0492), in which amounts were decreased by 43%
(Fig. 4C). Soluble A levels were unchanged with high-dose curcumin treatment (F(1,48) = 0.192;
p = 0.66).
Low doses of curcumin reduces plaque burden in APPSw brains
To evaluate whether curcumin treatment affected plaque pathology,
cryostat hemibrain sections from Tg+ control and Tg+ low-dose curcumin-treated mice were immunostained with an antibody against A1-13 (DAE). Two-factor ANOVA (treatment × region) revealed a significant reduction in plaque burden in curcumin-treated animals (F(1,60) = 4.74; p = 0.03), in which amyloid burden was decreased by 43.6% in treated
animals compared with untreated animals (Fig. 4B).
Additional analysis of the data showed that total area of plaques was
also decreased by 42.7% in curcumin-treated animals (with square root
transformation to achieve the homogeneity of variance required for
ANOVA; p = 0.01). The mean number of plaques was
reduced 32.6% (log transformation for homogeneity of variance; p = 0.045). Although there was a mean 14% decrease in
the size of the plaque with curcumin treatment, this observation was
not statistically significant (p = 0.33). The
mean diameter of the plaque was also not statistically reduced
(p = 0.70).
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DISCUSSION |
In this study, we report that the Indian spice curcumin suppresses
indices of inflammation and oxidative damage in the brains of APPSw
mice, factors that have been implicated in AD pathogenesis. Furthermore, low, nontoxic doses of curcumin decrease levels of insoluble and soluble amyloid and plaque burden in many affected brain regions.
Curcumin is a potent anti-inflammatory compound. Part of its NSAID-like
activity is based on the inhibition of nuclear factor  B
(NFB)-mediated transcription of inflammatory cytokines (Xu et al.,
1998), inducible nitric oxide synthase (iNOS) (Chan et al., 1998), and
cyclooxygenase 2 (Zhang et al., 1999). Elevated IL-1 has been linked to
neuroinflammatory cascades involved in neuritic plaque pathogenesis
(Sheng et al., 1996; Griffin et al., 1998) and in age-related LTP
deficits (Murray and Lynch, 1998). Both low and high doses of curcumin
were effective in significantly lowering our principal index of
inflammation, the proinflammatory cytokine IL-1 by 57-61.8%,
suggesting that inflammation was reduced in curcumin-treated animals.
GFAP, an astrocytic marker associated with injury and inflammatory
processes, was also significantly reduced with low-dose curcumin
treatment. Similarly, another index of inflammation, PT immunolabeling
of microglia in cortical and hippocampal neuronal layers, was
significantly reduced by curcumin treatment.
Extensive evidence of oxidative damage has been reported in AD (Conrad
et al., 2000; Praticò and Delanty, 2000; Varadarajan et al.,
2000) and results in lipid peroxidation products such as
4-hydroxynonenal and isoprostanes (Montine et al., 1998; Praticò et al., 1998). Immunohistochemical evidence of peri-plaque oxidative damage has been found in aged APPSw mice (Perry and Smith, 1997; Pappolla et al., 1998; Smith et al., 1998). In Tg+ animals, we detected
markedly elevated protein carbonyl formation using a convenient
quantifiable Western blot analysis of DNPH derivatized carbonyls. Low
and high doses of curcumin clearly suppressed the level of elevated
protein carbonyls by 46-61.5%, which is consistent with its known
antioxidant activity in brain (Rajakumar and Rao, 1994; Sreejayan and
Rao, 1994; Kaul and Krishnakantha, 1997). Oxidized protein levels were
not reduced in ibuprofen-treated Tg2576 mice (Lim et al., 2001).
Because ibuprofen reduces inflammation indexed by IL-1 and
plaque-associated microgliosis, this result suggests that reactive
oxygen species (ROS) secondary to inflammation in plaque-associated
reactive glia (Fig. 5) are not the
primary source of increased ROS-driven oxidative damage in this
-amyloidosis model. This conclusion is consistent with a recent
report in which isoprostanes were elevated in young mice before plaque
formation and associated reactive glia (Praticò et al., 2001).
These results suggest a combined antioxidant and NSAID approach to AD
prevention or therapeutics.
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Figure 5.
Curcumin blocks AD pathogenesis at multiple sites.
Curcumin can act as a scavenger of ROS, including NO and
peroxynitrite generated by reactive glia and hydroxyl radicals
generated by neurons as a result of direct A toxicity. Ibuprofen
(NSAID action at site 1) can inhibit microglial
activation and cytokine production but was not sufficient to reduce
oxidative damage. Antioxidants that can block ROS at multiple sites may
be required. Curcumin can also limit damage by inhibiting
NFB-induced iNOS, cyclooxygenase 2, and inflammatory cytokine
production by reactive glia. By blocking NFkB and reducing IL-1,
IL-6, and ApoE, curcurmin should reduce proamyloidogenic factors
(APOE, 1ACT). Finally, curcumin
can lower plasma and tissue cholesterol, potentially lowering A
production. LOX, Lipoxygenase; Cox-2,
cyclooxygenase 2; SCR, Scavenger receptors;
Fc, Fc Ig receptors.
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Studies indicate that there is a reduced age-adjusted prevalence of AD
in India (Ganguli et al., 2000), as well as a lower prevalence of
Parkinson's disease (Muthane et al., 1998). Both diseases are
linked to increased oxidative damage, including NO-based damage to a
specific protein, synuclein (Glasson et al., 2000). Curcumin may
effectively inhibit this damage.
Low-dose curcumin treatment significantly lowered both overall
insoluble amyloid and plaque burden by 39 and 43%, respectively. These
A-lowering effects were not mediated by reductions in APP expression
because we did not see any decrease in APP production in the SDS
fraction of curcumin-treated mice using Western blots with C-terminal
anti-APP681-695 antibody (Cole et al., 1992) (data not shown).
Although we did not see any consistent effect on APP levels, additional
experiments are required to determine whether curcumin influences APP
processing. These findings are consistent with previous observations
seen in ibuprofen-treated animals (10-16 months old), in which amyloid
levels and plaque pathology were decreased by ~50% (Lim et al.,
2000). High-dose curcumin treatment, however, did not affect the amount
of insoluble amyloid. Soluble A levels were also significantly
lowered by 43% in animals treated with low doses of curcumin, which is
consistent with previous observations seen in mice treated with
ibuprofen (Lim et al., 2000). Because "soluble A" fractions may
be involved with neurotoxicity, our data suggest that NSAIDs such as
curcumin and ibuprofen can protect against neurotoxicity by reducing
the level of these fractions.
Potential mechanisms underlying these curcumin treatment effects are
multifactorial, as illustrated in a schematic diagram (Fig. 5).
Curcumin suppressed microgliosis in neuronal layers but failed to
reduce microgliosis within plaques and even significantly increased
microgliosis immediately adjacent to plaques, raising the possibility
that it may stimulate microglial phagocytosis of amyloid. Other
possible mechanisms include inhibition of IL-1-induced increases in
alpha-1-antichymotrypsin (1ACT) and
NFB-mediated transcription of apolipoprotein E (ApoE). Both
1ACT (Rozemuller et al., 1990; Shoji et al.,
1991; Aksenova et al., 1996) and ApoE (Wisniewski and Frangione, 1992;
Wisniewski et al., 1994; Weisgraber and Mahley, 1996; Beffert et al.,
1999) have been shown to be proamyloidogenic in APP transgenic mice.
Curcumin can reduce two other proamyloidogenic pathways: oxidative
damage (Bush et al., 1994; Friedlich and Butcher, 1994; Hensley et al.,
1994) and cholesterol levels (Soudamini et al., 1992; Ramirez-Tortosa
et al., 1999; Kamal-Eldin et al., 2000). Cholesterol could promote
amyloidogenesis by regulating - and -secretase activity (Bodovitz
and Klein, 1996; Frears et al., 1999; Wolozin, 2001).
In addition to the illustrated inflammation-related targets, curcumin
is also reported to inhibit lipoxygenases and phospholipase D (Yamamoto
et al., 1997; Began and Sudharshan, 1998; Skrzypczak-Jankun et al.,
2000), which could contribute to overall NSAID or neuroprotective function. Given that there are multiple curcumin targets with varying
dose-response curves, it is not surprising that some effects are dose
related. For example, the amyloid reduction effect was dose-dependent
and lost at 5000 ppm. One explanation for this effect may be that high
doses of curcumin appear to suppress glial amyloid clearance in
organotypic hippocampal slice cultures (T. Chu, G. P. Lim, and
G. M. Cole, our unpublished observations), which could counterbalance
any anti-amyloidogenic effects. Ongoing efforts at dissection of the
relative importance of the different possible pathways for the amyloid
reduction effects by curcumin may or may not reveal a single essential
mode of action. In fact, the ability of curcumin to partially block
multiple pathways implicated in AD pathogenesis may potentially provide
greater in vivo efficacy than more potent but specific
inhibitors of any of the individual targets.
Curcumin has an extensive history as a food preservative and medicinal
herb in India (Ammon and Wahl, 1991), and it is possible that
widespread curcumin use may contribute to the reduced age-adjusted prevalence of AD in India (Ganguli et al., 2000). Studies have consistently shown that curcumin is relatively nontoxic and has few
side effects at doses greater than the low dose tested in our mice.
(Kelloff et al., 1991, 2000). Toxicity studies performed at 2000 mg/kg,
which is 83-fold greater than our low-dose curcumin treatment (~24
mg/kg), revealed no mortalities in any group of mice tested; the
compound also had a low ulcerogenic index (Srimal and Dhawan, 1972).
Even with the high-dose curcumin treatment (5000 ppm), which is 31-fold
greater than our low dose of curcumin, there was no impact on
presynaptic markers and no increase in GFAP in any region, consistent
with the absence of overt CNS toxicity (data not shown). Although side
effects have been limited in chronic animal and short-term clinical
studies, sustained clinical trials are needed to establish the safety
of chronic curcumin at antioxidant and anti-inflammatory doses.
In summary, at the relatively low, 160 ppm dose, curcumin significantly
suppressed the inflammatory cytokine IL-1 and the astrocytic
inflammatory marker GFAP, reduced oxidative damage, and decreased
overall insoluble amyloid, soluble amyloid, and plaque burden. In a rat
intraventricular A infusion model, a similar dose of dietary
curcumin reduced an isoprostane index of oxidative damage, amyloid
plaque burden, and A-induced spatial memory deficits in the Morris
water maze (Frautschy et al., 2001). Hence, curcumin is not only
efficacious at multiple levels but may have fewer side effects and
toxicity issues than many other NSAIDs, including ibuprofen. Together,
the multiple beneficial effects of curcumin make it a promising agent
for controlled clinical trials to establish its safety and efficacy as
a chronic antioxidant and NSAID prophylactic for prevention or
treatment of Alzheimer's and possibly other neurodegenerative diseases
of aging, such as Parkinson's disease.
| |
FOOTNOTES |
Received July 12, 2001; revised Aug. 6, 2001; accepted Aug. 22, 2001.
This work was supported by National Institute on Aging Grant AG13471
(G.M.C.), Veterans Affairs Merit, the Alzheimer Association, and The
Elizabeth and Thomas Plott Family Foundation. We thank Dr. Karen Hsiao
Ashe for her continued support and collaboration in studies pertaining
to the Tg2576 mouse. We acknowledge Boris Oks, John Alcantara, Veronica
Talamantes, and Ulises Garcia for their excellent work genotyping the
transgenic mice. We are also grateful to Dr. Judith Harker for her help
with the statistical analyses.
Correspondence should be addressed to Dr. Gregory M. Cole, Greater Los
Angeles Veterans Affairs Healthcare System, GRECC11E, University
of Los Angeles, Departments of Medicine and Neurology (San
Fernando Valley Program), 16111 Plummer Street, Sepulveda, CA 91343. E-mail: gmcole{at}ucla.edu.
| |
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