Abstract
A long-term intervention (2.69 years) with an antioxidant diet, behavioral enrichment, or the combined treatment preserved and improved cognitive function in aged canines. Although each intervention alone provided cognitive benefits, the combination treatment was additive. We evaluate the hypothesis that antioxidants, enrichment, or the combination intervention reduces age-related β-amyloid (Aβ) neuropathology, as one mechanism mediating observed functional improvements. Measures assessed were Aβ neuropathology in plaques, biochemically extractable Aβ40 and Aβ42 species, soluble oligomeric forms of Aβ, and various proteins in the β-amyloid precursor protein (APP) processing pathway. The strongest and most consistent effects on Aβ pathology were observed in animals receiving the combined antioxidant and enrichment treatment. Specifically, Aβ plaque load was significantly decreased in several brain regions, soluble Aβ42 was decreased selectively in the frontal cortex, and a trend for lower Aβ oligomer levels was found in the parietal cortex. Reductions in Aβ may be related to shifted APP processing toward the non-amyloidogenic pathway, because α-secretase enzymatic activity was increased in the absence of changes in β-secretase activity. Although enrichment alone had no significant effects on Aβ, reduced Aβ load and plaque maturation occurred in animals receiving antioxidants as a component of treatment. Aβ measures did not correlate with cognitive performance on any of the six tasks assessed, suggesting that modulation of Aβ alone may be a relatively minor mechanism mediating cognitive benefits of the interventions. Overall, the data indicate that multidomain treatments may be a valuable intervention strategy to reduce neuropathology and improve cognitive function in humans.
Introduction
Increasing evidence from human studies suggests that dietary and environmental interventions provide cognitive benefits and improve brain health, particularly in aged populations. For example, age-related cognitive decline was lessened by increased physical activity (Erickson and Kramer, 2009) or an “enriched environment” such as provided by cognitive training (Willis et al., 2006). Similarly, various dietary interventions rich in antioxidants may slow age-related cognitive decline and reduce the risk of Alzheimer's disease (AD) (Gray et al., 2003; Zandi et al., 2004; Dai et al., 2006). Studies in animal models provide several advantages over human studies in that precise dietary and behavioral protocols can be maintained over an extended time period, and effects on both cognitive function as well as underlying brain mechanisms can be assessed. Aged canines provide a valuable model for investigating mechanisms that underlie cognitive impairment. Like humans, aged beagles undergo cognitive decline in multiple cognitive domains that correlate with neuropathological changes (Cummings et al., 1996; Head et al., 1998, 2000). In parallel, aged beagles naturally accumulate several types of neuropathology that are consistent with human brain aging and AD, including cortical atrophy (Tapp et al., 2004), neuron loss (Siwak-Tapp et al., 2008), declines in neurogenesis (Siwak-Tapp et al., 2007), reduced brain-derived neurotrophic factor (BDNF) (Fahnestock et al., 2010), increased oxidative damage (Head et al., 2002; Skoumalova et al., 2003), and increased β-amyloid (Aβ) accumulation (Cummings et al., 1996; Head et al., 1998, 2000).
Previously, we demonstrated that an antioxidant diet (AOX), behavioral enrichment (ENR), or the combination treatment improves cognition and prevents age-related cognitive decline in aged canines (Cotman et al., 2002; Milgram et al., 2002). Mechanisms identified include the improved capacity of the brain to counteract oxidative stress (Opii et al., 2008), improved mitochondrial function (Head et al., 2009), reduced neuron loss (Siwak-Tapp et al., 2007, 2008), and increased availability of growth factors such as BDNF (Fahnestock et al., 2010). The combination of AOXs and ENR consistently produced greater benefits to cognition and neurobiological outcome measures than either treatment alone.
In this study, we hypothesized that AOX, ENR, or the combined treatment may reduce Aβ neuropathology in the canine brain. Previous studies have demonstrated that Aβ is reduced and cognition improved in transgenic AD mice by exposure to exercise (Adlard et al., 2005), ENR (Lazarov et al., 2005; Ambree et al., 2006; Costa et al., 2007), and select dietary compounds (Frautschy et al., 2001; Lim et al., 2001; Wang et al., 2008). However, other studies in transgenic AD mice have demonstrated improved cognition with ENR despite increased Aβ pathology (Jankowsky et al., 2005) and improved cognition in transgenic AD mice with AOX dietary supplementation without an affect on Aβ (Joseph et al., 2003; Sung et al., 2004; Quinn et al., 2007). Thus, the relationship between improved cognitive function and reductions in Aβ pathology is not clear-cut. To investigate whether cognitive improvements in the current study are paralleled by decreased Aβ pathology, we analyzed treatment effects on Aβ neuropathology and the amyloid precursor protein (APP) processing pathway in the aged canine.
Materials and Methods
Animals.
Twenty-four beagles ranging in age 8.05–12.35 years at the start of the study (mean ± SEM, 10.69 ± 0.25 years) were obtained from Lovelace Respiratory Research Institute (Albuquerque, NM) (supplemental Table 1, available at www.jneurosci.org as supplemental material). Animals were bred and maintained in the same environment, and all had documented dates of birth and comprehensive medical histories. All study dogs underwent extensive baseline cognitive testing as described previously (Milgram et al., 2002). Animals were subsequently ranked based on cognitive test scores and assigned to one of the following four treatment conditions: CC, control environment/control diet; EC, behavioral enrichment/control diet; CA, control environment/antioxidant diet; EA, behavioral enrichment/antioxidant diet. All animals, regardless of treatment condition, were evaluated annually on tests of visuospatial memory (Chan et al., 2002), object recognition memory (Callahan et al., 2000), and either size discrimination and reversal learning (Tapp et al., 2003) or black/white discrimination and reversal on consecutive years (Milgram et al., 2005). Cognitive results have been published for these animals (Cotman et al., 2002; Milgram et al., 2002). At the time the animals were killed, of the 24 aged animals that began the study, 23 dogs had received the intervention for >2 years (mean ± SEM, 2.69 ± 0.04 years) and ranged in age from 10.71 to 15.01 years (mean ± SEM, 13.31 ± 0.26 years), with one animal not completing the baseline phase of the study (supplemental Table 1, available at www.jneurosci.org as supplemental material). All research was conducted in accordance with approved Institutional Animal Care and Use Committee protocols.
Diet treatment.
The control and AOX test diets were formulated to meet the nutrient profile recommendations for adult dogs from the American Association of Feed Control Officials (1999). Control and test diets were identical in composition, other than inclusion of a broad-based cellular AOX and mitochondrial cofactor supplementation in the AOX test diet (supplemental Table 2, available at www.jneurosci.org as supplemental material). The control and test diet had the following differences in formulation on an as-fed basis, respectively: dl-α-tocopherol acetate (120 vs 1050 ppm), ascorbic acid as Stay-C (30 vs 80 ppm), acetyl-l-carnitine (20 vs 260 ppm), and dl-α-lipoic acid (20 vs 128 ppm). Based on an average weight of 10 kg/animal, the daily doses for each compound were 800 IU or 210 mg/d (21 mg · kg−1 · d−1) of vitamin E, 16 mg/d (1.6 mg · kg−1 · d−1) of vitamin C, 52 mg/d (5.2 mg · kg−1 · d−1) of acetyl-l-carnitine, and 26 mg/d (2.6 mg · kg−1 · d−1) of lipoic acid (supplemental Table 2, available at www.jneurosci.org as supplemental material). The AOX diet used compounds and doses that have shown some efficacy in epidemiological studies. However, human trials have often used much higher doses than those used in the current study, with AD patients receiving acetyl-l-carnitine at either 1 g/d (14.3–16.6 mg · kg−1 · d−1 assuming average weight of 60–70 kg) (Bonavita, 1986) or 2 g/d (Rai et al., 1990) and lipoic acid at dose levels up to 600 mg/d (8.5–10 mg · kg−1 · d−1 assuming average weight of 60–70 kg) (Hager et al., 2001). Fruits and vegetables were also incorporated at a 1:1 exchange ratio for corn, resulting in 1% inclusions of each of the following: spinach flakes, tomato pomace, grape pomace, carrot granules, and citrus pulp (supplemental Tables 2, 3, available at www.jneurosci.org as supplemental material).
Behavioral enrichment treatment. The behavioral ENR protocol consisted of four components: “social ENR” by housing animals in pairs, “environmental ENR” by providing novel play toys, “physical ENR” by providing two 20-min outdoor walks per week, and “cognitive ENR” through continuous cognitive testing consisting of 20–30 min/d. The cognitive ENR consisted of a landmark discrimination task, an oddity discrimination task (Milgram et al., 2002), and size concept learning (Tapp et al., 2003) as described previously (Cotman et al., 2002; Milgram et al., 2002).
Brain tissue.
Twenty minutes before induction of general anesthesia, animals were sedated by subcutaneous injection with 0.2 mg/kg acepromazine. Subsequently, surgery-level general anesthesia was induced by inhalation with 5% isoflurane and animals were exsanguinated. The brain was removed and sectioned midsagitally, with the entire left hemisphere immediately placed in 4% paraformaldehyde for 48–72 h at 4°C before long-term storage in PBS with 0.05% sodium azide at 4°C. The remaining right hemisphere was sectioned coronally (1-cm-thick sections) and flash frozen at −80°C. The dissection procedure was completed within 20 min. The postmortem interval for all animals was 35–45 min.
Aβ immunohistochemistry and quantification.
Following previously published protocols (Head et al., 2008), tissue from the left hemisphere was sectioned at 40 μm by Neuroscience Associates, followed by immunohistochemical processing. Briefly, free-floating sections containing the prefrontal, parietal, cingulate, entorhinal, and occipital cortices were pretreated with 90% formic acid, and Aβ plaques were detected with anti-Aβ1-17 (mouse monoclonal 6E10 antibody, 1:5000; Signet Laboratories) and visualized with DAB (Vector Laboratories). Control experiments in which primary or secondary antibody was omitted resulted in negative staining. The procedure for quantifying Aβ loads has been reported previously (Head et al., 2000). Briefly, 10 images were captured using a 20× objective in each brain region, and the area occupied by Aβ was quantified using grayscale thresholding (NIH Image) to obtain “Aβ loads.” Results were confirmed with an additional set of sections at least 200 μm away.
Maturation gradient of Aβ deposition (Aβ type).
Aβ deposition in the canine frontal cortex is a progressive age-related process beginning with diffuse deposits in the deep cortical layers, followed by the development of deposits in outer cortical layers. To assess the severity of Aβ pathology across treatment groups, we characterized Aβ maturation patterns in the same brain regions in which Aβ load was assessed, using methods described previously (Satou et al., 1997). Briefly, type 0 described regions without any Aβ plaque pathology; type 1 was characterized by small, faint, round Aβ deposits (<180 μm in diameter), usually in deep cortical layers V and VI; type 2 were diffuse, cloud-like deposits that often fused together in the deep layers and occasionally spread to the superficial layers; type 3 had both diffuse deposits like those of type 2 in deep layers and dense, round plaques (<120 μm but sometimes over 200 μm) in superficial layers; and type 4 consisted solely of dense, round plaques throughout all layers of cortex. Sections were analyzed at several magnifications as needed for clarity and then assigned the correct type. All cases with Aβ type 0, 1, or 2 were considered “early-stage” pathology, whereas all cases with Aβ type 3 or 4 contained plaques in the superficial layers and were considered “late-stage” pathology.
Aβ ELISA.
To detect differences among treatment groups in the prefrontal, parietal, temporal, and occipital cortices, we used previously published methods (Head et al., 2008). Briefly, frozen cortical samples were sequentially extracted in radioimmunoprecipitation assay (RIPA) buffer [pH 8, 50 mm Tris-HCl, 150 mm NaCl, 0.5% deoxycholate, 0.1% SDS, 1% Triton X-100, and protease inhibitor cocktail (MP Biomedicals)] to obtain a soluble RIPA fraction and a RIPA pellet, which was resuspended in a 70% formic acid buffer (FA) to measure insoluble Aβ. All FA samples were neutralized in neutralization buffer, and RIPA and FA preparations were run in triplicate on ELISA plates coated with a monoclonal anti-Aβ1-16 antibody (kindly provided by Dr. William Van Nostrand, Stony Brook University, Stony Brook, NY). Detection was by monoclonal HRP-conjugated antibodies anti-Aβx-40 (MM32-13.1.1) or anti-Aβx-42 (MM40-21.3.1) (both antibodies kindly provided by Dr. Christopher Eckman, Mayo Clinic Jacksonville, Jacksonville, FA) (Kukar et al., 2005; McGowan et al., 2005). For standards, dilutions of Aβ1-40 and Aβ1-42 peptides (Bachem California) were used after a pretreatment with hexafluoroisopropanol to prevent fibril formation. The inclusion of a series of controls to test the absorbance of buffers, samples, and antibodies yielded negative results.
Western blot.
Parietal cortex was used for analysis of Aβ oligomer levels and proteins in the APP processing pathway [TACE (tumor necrosis factor-α converting enzyme), ADAM10 (a disintegrin and metalloprotease 10), and C-terminal fragments (CTFs)] because this region showed decreased Aβ plaque load in response to treatments. Protein levels of APP, insulin degrading enzyme (IDE), and neprilysin were quantified in the parietal, prefrontal, hippocampal, and occipital regions. For oligomer studies, pulverized tissue samples were extracted in PBS buffer (powder packet from Sigma-Aldrich) [pH 7.4, 0.2% NaN3 with Complete Mini protease inhibitor (Roche Diagnostics)]. For all other proteins, frozen tissue was homogenized in RIPA buffer at 1 ml buffer/150 mg pulverized tissue weight. All samples were centrifuged at 100,000 × g for 1 h at 4°C, and soluble fractions were recovered and brought to an equal protein concentration by BCA (Pierce Biotechnology). For the detection of the 56 kDa Aβ aggregate, Aβ was immunoprecipitated from soluble PBS samples by overnight incubation with Protein A/G PLUS-Agarose bead complex (Santa Cruz Biotechnology) and 5 μl of the anti-Aβ 6E10 antibody (mouse monoclonal for Aβ1-17; Covance). Unbound proteins were removed by washing with PBS buffer, and samples were centrifuged at 2500 rpm for 5 min at 4°C to pellet the bead–antibody–protein complex. Loading buffer (2.5 mm Tris, pH 6.8, 2% SDS, 0.007% bromophenol blue, 4% β-mercaptoethanol, and 10% glycerol) was added to each sample, followed by boiling at 100°C for 5 min. For Western blots, equal protein amounts were loaded for each sample on 4–20% Tris-HCl Criterion gels (Bio-Rad), followed by transfer to sequi-blot polyvinylidene difluoride membranes (Bio-Rad). For the oligomer studies, incubations were in Tris-buffered saline with 0.01% Tween 20 (TTBS), specifically using 3% BSA/TTBS for all blocking and antibody incubations with β-actin (mouse, 1:5000; Abcam) and A11 antibodies (rabbit, 1:1000; Millipore Bioscience Research Reagents) (Kayed et al., 2003). For other protein analyses, incubations were in 5% milk/TTBS. The antibodies used in Western blots were β-actin (rabbit, 1:5000; Abcam), glyceraldehyde 3-phosphate dehydrogenase (rabbit, 1:10,000; Millipore Bioscience Research Reagents), the N-terminal anti-Aβ antibody 6E10 for APP (mouse, 1:5000; Signet Laboratories), the C-terminal anti-Aβ antibody CT20 for full-length APP and CTFα and CTFβ (rabbit, 1:2000, raised against the C-terminal 20 aa of APP), antibodies to clearance enzymes IDE (mouse, 1:250; Covance) and neprilysin (rabbit, 1:50; Abcam), and an antibody to the precursor and mature form of the α-secretase (αSEC) enzyme TACE/ADAM17 (rabbit, 1:2000; Millipore Bioscience Research Reagents) or ADAM10 (rabbit, 1:500; Millipore Bioscience Research Reagents). Secondary antibodies were HRP-conjugated IgG anti-mouse (goat anti-mouse, 1:5000; Bio-Rad) or anti-rabbit (goat anti-rabbit, 1:10,000; Bio-Rad or Rockland Immunochemicals) as needed. Supersignal Chemiluminescent Substrate (Pierce Biotechnology) was used to visualize HRP activity on Hyperfilm ECL (GE Healthcare). The omission of primary antibody resulted in negative staining. Immunoblots were quantified using NIH Image J software, with optical density (OD) measures adjusted for individual β-actin OD levels.
α and β-secretase activity assays.
These protocols have been published previously (Nistor et al., 2007). Briefly, frozen tissue was prepared according to protocols provided by the commercial supplier of the Secretase Activity kits (R & D Systems). A total of 125 μg of protein (2.5 μg/μl in 50 μl of total per well, OD read at 2 h) was used for αSEC, and a total of 7.5 μg of protein (0.15 μg/μl in 50 μl total per well, OD read at 30 min) was used for the βSEC assay. All samples were run in triplicate, and assays were replicated to confirm results.
Statistical analyses.
To preclude bias, all data were collected while blind with respect to the experimental conditions. All statistical analyses were performed using SPSS for Windows, SYSTAT, or SAS, and graphs were produced using SigmaPlot. Generalized estimating equations (Zeger and Liang, 1986) and ANOVAs were used to compare mean Aβ across treatment groups. Post hoc analyses considered the main effect of the AOX diet (comparing the CC+EC groups vs the CA+EA groups) and the behavioral ENR (comparing the CC+CA groups vs the EC+EA groups). In data measures in which normality and variance assumptions were violated and not rectifiable by converting raw data to Log10 scores, group differences were assessed according to the nonparametric Kruskal–Wallis analysis for multiple samples and the Mann–Whitney U analysis for two independent samples. Correlations were assessed using the Pearson's coefficient or Spearman's rank nonparametric statistic as needed.
Results
To define the effects of AOX, ENR, or the combined intervention on Aβ pathology and Aβ processing in the canine brain, we analyzed treatment effects on extracellular Aβ plaque load, levels of biochemically extractable Aβ40 and Aβ42 species, soluble oligomeric forms of Aβ, and the APP processing pathway.
Treatment effects on extracellular plaque pathology
Aβ plaque immunostaining with the 6E10 antibody was quantified in the prefrontal, cingulate, parietal, entorhinal, and occipital cortices, revealing a differential treatment and brain region effect (Fig. 1). When all brain regions were considered together, Aβ plaque load was significantly reduced in the combined EA treatment group to 19% of untreated control (CC) levels (p = 0.01), whereas AOX treatment alone reduced Aβ plaque load in the CA group to 41% of untreated control (CC) levels (p = 0.084) (Fig. 1A). In individual brain regions, the EA treatment group reduced Aβ plaque load to 18% of control (CC) levels in the cingulate cortex (p = 0.021), to 13% of control (CC) levels in the parietal cortex (p = 0.093), and to 10% of control (CC) levels in the entorhinal cortex (p = 0.077) (Fig. 1B). Representative images from the parietal and entorhinal cortex are shown in Figure 1, C and D, respectively.
Because the EA treatment group showed the largest overall effect on reducing Aβ plaque load, treatment groups were pooled according to AOX diet or ENR condition to determine the possible relative contributions of each intervention strategy. Thus, the pooled AOX analysis consisted of control diet groups (CC+EC) compared with the AOX diet groups (CA+EA), whereas the pooled ENR analysis compared the control environment groups (CC+CA) versus the behavioral enrichment groups (EC+EA). Significantly lower Aβ load was detected in animals receiving the AOX diet (Fig. 2A,B) but not in animals receiving ENR treatment (Fig. 2C,D). The pooled AOX groups showed significantly lower Aβ load in the total brain analysis (p = 0.004) (Fig. 2A), as well as in the cingulate cortex (p = 0.032) and the parietal cortex (p = 0.043) (Fig. 2B). These data indicate that the reduction in Aβ plaques is stronger in animals receiving the AOX diet as a component of treatment than in animals receiving ENR as a component of treatment.
Because the duration of treatment spanned an extensive time period (2.69 years), we hypothesized that the treatment effects may reflect a change in the maturation pattern of Aβ accumulation. With age, Aβ accumulates in a stereotypical laminar pattern within the cortex, reflecting a maturation gradient with early-stage deposits in the deep layers and late-stage deposits occupying more superficial layers (Satou et al., 1997) (Fig. 3A). To determine whether AOX or ENR conditions influence plaque maturation, the percentage of animals exhibiting either early-stage or late-stage Aβ plaque pathology was calculated in the pooled AOX or ENR groups. Fewer late-stage deposits were observed in the prefrontal, cingulate, parietal, and entorhinal cortices in animals receiving the AOX diet as a component of treatment (Fig. 3B). In contrast, no consistent difference in early-stage and late-stage plaque pathology was observed in groups receiving ENR as a component of treatment (p > 0.05) (data not shown). These results suggest that the AOX diet may slow the progression of Aβ accumulation within individual brain regions.
Treatment effects on Aβ40, Aβ42, and Aβ oligomers
To determine whether the different interventions affected amyloid species and assembly states, we assessed the levels of soluble and insoluble Aβ40 and Aβ42 species and levels of Aβ oligomers. Soluble and insoluble Aβ40 or Aβ42 species were measured by ELISA in the prefrontal, parietal, temporal, and occipital cortices (Fig. 4). Mean Aβ40 was lowest in groups receiving the combined intervention, with the largest observed difference occurring in the parietal region, but no significant differences in soluble Aβ40 (Fig. 4A) or insoluble Aβ40 (Fig. 4B) were detected in any brain region. Significantly lower levels of soluble Aβ42 were detected selectively in the prefrontal cortex of the EA group compared with CC controls (p = 0.032) (Fig. 4C), whereas no significant changes in insoluble Aβ42 were observed in any region (Fig. 4D). Soluble and insoluble Aβ42/40 ratios showed no significant differences between groups in any brain region (p > 0.05) (data not shown).
We next assessed whether Aβ oligomers are present in the canine brain and whether oligomer levels were modulated by AOX, ENR, or the combination treatment. Oligomeric proteins were assayed in the parietal cortex, because this region showed marked reductions in Aβ plaque load after treatment. An oligomeric protein migrating at 56 kDa was detected (Fig. 5A) that appears similar to the oligomeric species reported previously in transgenic mouse models of AD. Quantification of the 56 kDa band revealed an ∼50% reduction (nonsignificant trend) and reduced within-group variability selectively in the combination EA treatment group (Fig. 5B).
These results indicate that the AOX or ENR interventions alone had little effect on steady-state levels of Aβ40 and Aβ42 species and oligomeric assembly states. However, the combined EA treatment resulted in lower levels of soluble Aβ42 in the prefrontal cortex and a trend for reduced levels of the 56 kDa oligomer in the parietal cortex.
Changes in the APP processing pathway
Together, the above data reveal decreased Aβ load in the canine brain, particularly in response to the combined EA treatment. Several mechanisms may underlie the reduction in Aβ load, including increased clearance by Aβ degrading enzymes, decreased availability of APP, or altered APP processing favoring the non-amyloidogenic pathway.
Levels of Aβ degrading enzymes and APP protein were analyzed by Western blot in the prefrontal, parietal, hippocampal, and occipital brain regions. The amyloid clearance proteins neprilysin and IDE remained steady across all treatment groups in all brain regions examined (p > 0.05) (data not shown). Similarly, there were no trends or significant differences in steady-state levels of total APP protein levels in any brain regions, as assessed using both an N-terminal or a C-terminal anti-Aβ antibody (p > 0.05) (data not shown). These results indicate that neither increased availability of clearance proteins nor decreased availability of APP protein appear to contribute to the observed reductions in Aβ load after treatment with AOX, ENR, or the combined intervention.
Because Aβ accumulation likely reflects a balance between production and clearance mechanisms, we next examined whether differential APP cleavage might explain the reductions in Aβ attributable to enhanced non-amyloidogenic processing. Key proteins in the APP processing pathway were assessed by Western blot in the parietal cortex, a region in which Aβ was decreased in response to treatments. CTFα and CTFβ, from APP cleavage by αSEC and βSEC, respectively, remained unchanged with any treatment. Similarly, there were no significant differences in βSEC enzymatic activity (p > 0.05) (data not shown). However, αSEC enzyme activity, indicative of non-amyloidogenic APP processing, was significantly increased in the combined EA treatment group (20%, p < 0.05) but not in the individual AOX or ENR treatment groups (Fig. 6A). βSEC activity was unchanged in all treatment groups. To determine which αSEC protein might underlie increases in enzymatic activity, protein levels of the major αSEC candidates TACE and ADAM10 were quantified. TACE levels were not significantly altered among groups (p > 0.05) (data not shown), but levels of the precursor to ADAM10 showed a nonsignificant increase in groups receiving the AOX diet (CA and EA) but not enrichment alone (EC) (Fig. 6B,C). Protein levels of the mature form of ADAM10 remained unchanged.
Together, these results indicate that the treatment interventions do not alter levels of APP or two of the major clearance proteases, neprilysin and IDE. However, combined EA treatment appears to increase αSEC enzymatic activity, in the absence of a significant change in βSEC, suggesting a shift to the non-amyloidogenic pathway, consistent with the reductions in Aβ plaque deposition observed in the EA treatment group.
Relationship of cognitive performance with measures of Aβ pathology
We next assessed whether changes in Aβ pathology correlated with the improved cognitive performance that was reported previously in these dogs in response to ENR, AOX, or the combination of the interventions. Six performance measures had been evaluated previously across all four groups of dogs: discrimination errors and discrimination reversal errors in year 2 of treatment, spatial memory phase 10 errors (years 2 and 3 of treatment), and black/white intensity discrimination errors and reversal errors (year 3 of treatment). Two-tailed Pearson's correlations were calculated for performance and the following variables for the 23 dogs: total Aβ load across brain regions, Aβ load in individual brain regions, levels of Aβ40, Aβ42, oligomers, and αSEC activity. No significant correlation or trend for a correlation was found between any cognitive measure and any measure of Aβ pathology or APP processing. For example, looking at Aβ load across brain regions and behavioral task performance in year 3 of treatment, Pearson's correlations were as follows: spatial memory performance (r = 0.198, p = 0.366), black/white intensity discrimination errors (r = −0.096, p = 0.662), and black/white intensity discrimination reversal errors (r = −0.134, p = 0.543). These results suggest that improvements in cognition in response to treatments were minimally related to changes in Aβ pathology.
Discussion
Previously, we have shown that a long-term intervention (2.69 years) with an AOX diet, behavioral ENR, or the combined EA treatment preserves and improves cognitive function in aged canines. Although each intervention alone provided benefits, the combination treatment had additive benefits for cognition (Cotman et al., 2002; Milgram et al., 2002). Here we evaluated the hypothesis that AOX and ENR interventions reduce age-related Aβ neuropathology as one mechanism that may contribute to the observed cognitive improvement.
The combination of dietary AOXs and behavioral ENR interventions is optimal
Overall, across the treatment groups, the strongest and most consistent effects on Aβ pathology were observed in canines receiving the combined EA intervention. After combined EA treatment, Aβ load was significantly decreased in several brain regions, soluble Aβ42 was decreased selectively in the frontal cortex, and the Aβ56 kDa oligomer showed a trend for lower levels and reduced variability in the parietal cortex. The increase in αSEC activity, in the absence of changes in βSEC activity, suggests that reductions in Aβ may be related to a shift in APP processing toward the non-amyloidogenic pathway. Previously, increased αSEC activity in the absence of changed β- or γ-secretase activity has been linked to moderate decreases in Aβ40 and Aβ42 in calorie-restricted primates (Qin et al., 2006), suggesting that shifted processing to the non-amyloidogenic pathway may serve to reduce Aβ in higher animal models. In addition, our findings are consistent with effects of other natural compounds that reduced Aβ and increased αSEC activity, such as Ginkgo biloba (Colciaghi et al., 2004) and green tea (Levites et al., 2003; Rezai-Zadeh et al., 2005; Obregon et al., 2006). The absence of a detectable increase in the CTFα fragment concomitant with the 20% increase in αSEC activity may reflect an effect on APP processing that is below detection or that the CTFα fragment is rapidly degraded.
To estimate the relative contribution of either AOX or ENR treatment to reductions in Aβ load, treatment groups were pooled according to the inclusion of AOX or ENR as a component of treatment. This analysis revealed significantly reduced Aβ load when animals were pooled according to the presence of AOXs (∼50% reduction) but not when pooled according to ENR (∼20% reduction). Similarly, the pooled AOX groups (but not the ENR groups) exhibited more early-stage deposits and fewer late-stage deposits, indicating a slower Aβ plaque maturation and accumulation process. These data indicate that the reduction in Aβ plaques is stronger in animals that received the AOX diet as a component of treatment compared with ENR. Interestingly, the effect of the AOX intervention on reducing Aβ load and maturation are enhanced when combined with ENR, resulting in a 80% reduction in amyloid plaque load, although ENR on its own had little effect.
The concept that combined dietary and behavioral interventions can have superior effects to either approach alone builds on previous literature. For example, in mice, the effects of voluntary exercise (a component of the ENR paradigm) was improved when exercise was combined with dietary administration of the plant flavonol epicatechin (van Praag et al., 2007). In addition, in rats, combining exercise with the ω-3 fatty acid docosahexaenoic acid resulted in synergistic effects on improving cognition and enhancing synaptic plasticity in the BDNF pathway (Wu et al., 2008). Similarly, we demonstrate that combined dietary and behavioral interventions are more effective at reducing amyloid pathology than either intervention alone.
Does Aβ accumulation influence cognitive decline in higher animal models?
Our data indicate that the combination of AOX and ENR significantly reduced Aβ load in the brain, with only modest effects on levels of soluble and insoluble Aβ species and assembly states. On one hand, the reduction in amyloid load in the absence of reductions in steady-state amyloid levels seems paradoxical. However, Aβ immunization, which decreases Aβ load, has been associated with unchanged or even increased steady-state Aβ levels in humans (Patton et al., 2006). The observed reductions in Aβ load and more immature plaque distribution with EA treatment may reflect a compartmentalization of amyloid such that, with reduced amyloid burden overall, fewer cellular elements are exposed to extracellular amyloid. The more immature plaque distribution pattern may further allow select brain regions to function in a more youthful state even with minimal changes in amyloid levels.
The importance of Aβ accumulation in driving cognitive decline in higher animal models of aging is under ongoing debate. It is well accepted that Aβ impairs cognition in transgenic mouse models of AD, but the case is less clear in higher animal models with a natural course of Aβ accumulation. For example, in aged canines, although Aβ immunization substantially reduced Aβ plaque load and Aβ levels, cognitive performance was essentially unaffected, with the exception of some improvement and maintenance in executive function on a reversal learning task after a 2+ year treatment (Head et al., 2008). By comparison, in aged canines given AOX and ENR treatments and administered the same cognitive tasks as immunized animals, there were robust cognitive improvements across multiple measures of learning and memory (Cotman et al., 2002; Milgram et al., 2002). Similar to the canine immunization results, in recent human clinical trials, immunization of AD patients reduced Aβ load but had only minor effects on cognitive improvement and did not slow disease progression (Gilman et al., 2005; Holmes et al., 2008; Kokjohn and Roher, 2009). This literature suggests that factors in addition to Aβ neuropathology may be important determinants of cognitive performance and the rate of cognitive decline.
The modest effects of AOX, ENR, or the combination intervention on Aβ40 and Aβ42 levels in canines may provide insight into human brain aging. In humans, various lifestyle factors (e.g., education, social networks, and activity participation) can help build cognitive reserve, allowing the brain to tolerate more amyloid pathology, and maintain intact cognitive function (Bennett et al., 2006; Roe et al., 2008a,b).
Multiple mechanisms may underlie the cognitive benefits of AOX and ENR interventions
Multiple mechanisms may ultimately determine the capacity of the AOX and ENR interventions to improve cognitive function. Several mechanisms have been identified, including improved capacity to counteract oxidative stress (Opii et al., 2008), improved mitochondrial function (Head et al., 2009), preserved neuron number (Siwak-Tapp et al., 2008), and increased availability of growth factors such as BDNF (Fahnestock et al., 2010). Interestingly, the combined EA treatment appears to have additive or synergistic effects on several neurobiological endpoints. The molecular endpoint showing the greatest effects of the interventions to date has been an improved capacity to counteract age-related oxidative damage (Opii et al., 2008). In canines, the AOX, ENR, or combined EA intervention reduced the extent of oxidative damage and improved the AOX reserve system, by decreasing levels of oxidative stress biomarkers and increasing activity of key enzymes involved in energy metabolism and regulation of oxidative stress [e.g., Cu-Zn superoxide dismutase (SOD) and glutathione S-transferase (GST)] (Opii et al., 2008). The increases in SOD and GST enzymatic activity were positively correlated with improvements in cognitive performance (Opii et al., 2008). Similar to the correlation between oxidative enzymatic activity and cognitive performance, the extent of neurogenesis correlated with cognitive score across treatment groups, with the strongest relationship in the combined intervention (Siwak-Tapp et al., 2007). In contrast, changes in Aβ pathology observed in the current study did not correlate with improvements in cognitive performance based on the same cognitive tasks. This literature suggests that the AOX and ENR interventions may engage compensatory molecular mechanisms that build cognitive reserve, allowing the canine to maintain intact cognitive abilities despite the continued presence of Aβ in the brain (Bennett et al., 2006; Roe et al., 2008a,b).
Summary
Our data adds to a growing body of knowledge that changes in cognitive function in higher animal models and humans are not consistently linked to changes in amyloid neuropathology. In this study, treatment of aged dogs with AOX, ENR, or the combined intervention strongly improved cognitive function, although amyloid pathology overall was only moderately reduced. Although Aβ load was decreased, particularly with the combined intervention, steady-state levels of Aβ40 and Aβ42 and oligomeric assembly states were only modestly reduced, despite a shift of APP processing to the non-amyloidogenic pathway. Recent data confirm that multiple mechanisms, perhaps in parallel with modest reductions in Aβ, may contribute to the cognitive health and functional benefits provided by the interventions. Importantly, across all molecular mechanisms, including the Aβ pathway, the strongest effects consistently occurred in the combined EA treatment group, which also sustained the greatest cognitive benefits. These data suggest that multidomain treatments may be a valuable intervention strategy to reduce pathology and improve cognitive function in humans.
Footnotes
This work was supported by National Institutes of Health/National Institute on Aging Grants AG12694 and AG17066 and U.S. Department of the Army Contract DAMD17-98-1-8622. We thank the following people: Mihaela Nistor and Floyd Sarsoza for immunohistochemistry, Dr. Kim Green for ELISA, Drs. Paul Adlard and Wayne Poon for enzyme activity assays, and Dr. Lori-Ann Christie for manuscripts edits.
- Correspondence should be addressed to Dr. Carl W. Cotman, Institute for Brain Aging and Dementia, Department of Neurobiology and Behavior, 1226 Gillespie Neuroscience Research Facility, University of California, Irvine, Irvine, CA 92697-4540. cwcotman{at}uci.edu