Floy R. Stewart

Human apoE isoforms differentially regulate brain amyloid-β peptide clearance

Human apoE4 increases the concentration of soluble Aβ in the brain by impairing its clearance. Clearing the Debris in Alzheimer’s Disease The strongest risk factor for developing the common sporadic form of Alzheimer’s disease (AD) that occurs in old age is the ε4 allele encoding apolipoprotein E4 (apoE4). Two ε4 alleles can lower the age of onset of AD by 10 to 15 years. In contrast, the ε2 allele decreases the risk of developing this neurodegenerative disorder. APOE is important for lipoprotein metabolism, but how it might be involved in AD has remained unclear. It has been suggested that the apoE4 isoform might somehow help to drive accumulation of the peptide amyloid-β (Aβ), which forms amyloid plaques in the brain that contribute to neuronal death and are the characteristic hallmark of AD. In a tour de force study in humans and mice, Holtzman and his team at Washington University in St. Louis now show that apoE4 contributes to Aβ accumulation in the brain not by affecting Aβ synthesis but by affecting its clearance. First, the authors looked at the Aβ concentration in the cerebrospinal fluid (CSF) of cognitively normal individuals under age 70 carrying different APOE genotypes. They found that those with the ε4/ε4 genotype had a much lower CSF Aβ concentration than did those with the protective ε2/ε3 genotype. A CSF Aβ concentration of less than 500 pg/ml is an indication that Aβ peptide is accumulating in the brain and thus is not moving into the CSF. Next, the researchers analyzed imaging data using a dye called Pittsburgh compound B that binds to amyloid plaques in the brain and showed that those individuals with the ε4/ε4 genotype bound more dye than did those with the other APOE genotypes. They then moved to a mouse model of AD in which the mice expressed one of the three human apoE isoforms. They measured Aβ concentrations in the interstitial fluid of these mice using in vivo microdialysis and then looked at stained hippocampal sections from these mice. They found greater Aβ concentrations in both interstitial fluid and the hippocampus in mice expressing the human apoE4 isoform than in animals expressing either the E3 or E2 isoforms. They discovered that this difference in Aβ concentration between the mice carrying different APOE genotypes was present in young as well as aged mice, suggesting that it predates the appearance of amyloid plaques. They then measured clearance of Aβ from the interstitial fluid of young mice and showed that those with the human apoE4 isoform were less able to clear Aβ than those with the apoE2 or apoE3 isoforms. The researchers showed that processing of the amyloid precursor protein and generation of the Aβ peptide did not vary according to genotype, lending credence to the hypothesis that apoE4 affects clearance of Aβ but not its synthesis. This thorough study sheds new light on how apoE4 is implicated in AD and highlights the Aβ clearance pathway as a new target for developing drugs to slow or even halt the accumulation of amyloid plaques in patients with AD. The apolipoprotein E (APOE) ε4 allele is the strongest genetic risk factor for late-onset, sporadic Alzheimer’s disease (AD). The APOE ε4 allele markedly increases AD risk and decreases age of onset, likely through its strong effect on the accumulation of amyloid-β (Aβ) peptide. In contrast, the APOE ε2 allele appears to decrease AD risk. Most rare, early-onset forms of familial AD are caused by autosomal dominant mutations that often lead to overproduction of Aβ42 peptide. However, the mechanism by which APOE alleles differentially modulate Aβ accumulation in sporadic, late-onset AD is less clear. In a cohort of cognitively normal individuals, we report that reliable molecular and neuroimaging biomarkers of cerebral Aβ deposition vary in an apoE isoform–dependent manner. We hypothesized that human apoE isoforms differentially affect Aβ clearance or synthesis in vivo, resulting in an apoE isoform–dependent pattern of Aβ accumulation later in life. Performing in vivo microdialysis in a mouse model of Aβ-amyloidosis expressing human apoE isoforms (PDAPP/TRE), we find that the concentration and clearance of soluble Aβ in the brain interstitial fluid depends on the isoform of apoE expressed. This pattern parallels the extent of Aβ deposition observed in aged PDAPP/TRE mice. ApoE isoform–dependent differences in soluble Aβ metabolism are observed not only in aged but also in young PDAPP/TRE mice well before the onset of Aβ deposition in amyloid plaques in the brain. Additionally, amyloidogenic processing of amyloid precursor protein and Aβ synthesis, as assessed by in vivo stable isotopic labeling kinetics, do not vary according to apoE isoform in young PDAPP/TRE mice. Our results suggest that APOE alleles contribute to AD risk by differentially regulating clearance of Aβ from the brain, suggesting that Aβ clearance pathways may be useful therapeutic targets for AD prevention.

Neuronal activity regulates the regional vulnerability to amyloid-β deposition

Amyloid-β (Aβ) plaque deposition in specific brain regions is a pathological hallmark of Alzheimers disease. However, the mechanism underlying the regional vulnerability to Aβ deposition in Alzheimers disease is unknown. Herein, we provide evidence that endogenous neuronal activity regulates the regional concentration of interstitial fluid (ISF) Aβ, which drives local Aβ aggregation. Using in vivo microdialysis, we show that ISF Aβ concentrations in several brain regions of APP transgenic mice before plaque deposition were commensurate with the degree of subsequent plaque deposition and with the concentration of lactate, a marker of neuronal activity. Furthermore, unilateral vibrissal stimulation increased ISF Aβ, and unilateral vibrissal deprivation decreased ISF Aβ and lactate, in contralateral barrel cortex. Long-term unilateral vibrissal deprivation decreased amyloid plaque formation and growth. Our results suggest a mechanism to account for the vulnerability of specific brain regions to Aβ deposition in Alzheimers disease.

Endocytosis is required for synaptic activity-dependent release of amyloid-β in vivo

Aggregation of amyloid-beta (Abeta) peptide into soluble and insoluble forms within the brain extracellular space is central to the pathogenesis of Alzheimers disease. Full-length amyloid precursor protein (APP) is endocytosed from the cell surface into endosomes where it is cleaved to produce Abeta. Abeta is subsequently released into the brain interstitial fluid (ISF). We hypothesized that synaptic transmission results in more APP endocytosis, thereby increasing Abeta generation and release into the ISF. We found that inhibition of clathrin-mediated endocytosis immediately lowers ISF Abeta levels in vivo. Two distinct methods that increased synaptic transmission resulted in an elevation of ISF Abeta levels. Inhibition of endocytosis, however, prevented the activity-dependent increase in Abeta. We estimate that approximately 70% of ISF Abeta arises from endocytosis-associated mechanisms, with the vast majority of this pool also dependent on synaptic activity. These findings have implications for AD pathogenesis and may provide insights into therapeutic intervention.

Disruption of the Sleep-Wake Cycle and Diurnal Fluctuation of β-Amyloid in Mice with Alzheimer’s Disease Pathology

Decreased sleep and attenuation of circadian fluctuations in Aβ reflect amyloid-associated pathology in Alzheimer’s disease. Don’t Let Amyloid Keep You Awake at Night The accumulation in the brain of the neurotoxic β-amyloid (Aβ) peptide is a key event in the pathogenesis of Alzheimer’s disease (AD). Aβ accumulation in amyloid plaques begins about 10 to 15 years before cognitive decline and is already very substantial by the time memory and thinking problems begin. It is critical to determine whether there are functional and biochemical changes in the brain that are present when Aβ is accumulating but before the appearance of dementia to initiate therapy earlier as well as to assess the therapeutic effects of new drugs. Previous work has shown that soluble forms of Aβ fluctuate in the brain with the sleep-wake cycle. Now, Roh and colleagues show that diurnal fluctuation of Aβ occurs in different brain regions in young adult mice that develop accumulation of Aβ. However, Aβ fluctuation disappeared with the onset of amyloid plaque deposition, most likely due to insoluble Aβ plaques sequestering soluble forms of Aβ. Similar findings were seen in the cerebrospinal fluid of humans with genetic mutations that cause early-onset, autosomal dominant AD. Coincident with increasing Aβ accumulation, the researchers found that the amount of time mice were awake when they were supposed to be asleep increased by 50%. Actively immunizing mice with Aβ prevented amyloid plaque formation, as well as maintaining normal circadian Aβ fluctuation and normal sleep patterns. These findings suggest that changes in the sleep-wake cycle may be caused by Aβ accumulation. If analogous abnormalities in the sleep-wake cycle are present in cognitively normal and very mildly impaired humans who are developing AD pathology, the sleep-wake cycle may be a useful indicator of early brain dysfunction that could be assessed as an outcome measure in response to therapeutic interventions. Aggregation of β-amyloid (Aβ) in the brain begins to occur years before the clinical onset of Alzheimer’s disease (AD). Before Aβ aggregation, concentrations of extracellular soluble Aβ in the interstitial fluid (ISF) space of the brain, which are regulated by neuronal activity and the sleep-wake cycle, correlate with the amount of Aβ deposition in the brain seen later. The amount and quality of sleep decline with normal aging and to a greater extent in AD patients. How sleep quality as well as the diurnal fluctuation in Aβ change with age and Aβ aggregation is not well understood. We report a normal sleep-wake cycle and diurnal fluctuation in ISF Aβ in the brain of the APPswe/PS1δE9 mouse model of AD before Aβ plaque formation. After plaque formation, the sleep-wake cycle markedly deteriorated and diurnal fluctuation of ISF Aβ dissipated. As in mice, diurnal fluctuation of cerebrospinal fluid Aβ in young adult humans with presenilin mutations was also markedly attenuated after Aβ plaque formation. Virtual elimination of Aβ deposits in the mouse brain by active immunization with Aβ42 normalized the sleep-wake cycle and the diurnal fluctuation of ISF Aβ. These data suggest that Aβ aggregation disrupts the sleep-wake cycle and diurnal fluctuation of Aβ. Sleep-wake behavior and diurnal fluctuation of Aβ in the central nervous system may be functional and biochemical indicators, respectively, of Aβ-associated pathology.

In Vivo Microdialysis Reveals Age-Dependent Decrease of Brain Interstitial Fluid Tau Levels in P301S Human Tau Transgenic Mice

Although tau is a cytoplasmic protein, it is also found in brain extracellular fluids, e.g., CSF. Recent findings suggest that aggregated tau can be transferred between cells and extracellular tau aggregates might mediate spread of tau pathology. Despite these data, details of whether tau is normally released into the brain interstitial fluid (ISF), its concentration in ISF in relation to CSF, and whether ISF tau is influenced by its aggregation are unknown. To address these issues, we developed a microdialysis technique to analyze monomeric ISF tau levels within the hippocampus of awake, freely moving mice. We detected tau in ISF of wild-type mice, suggesting that tau is released in the absence of neurodegeneration. ISF tau was significantly higher than CSF tau and their concentrations were not significantly correlated. Using P301S human tau transgenic mice (P301S tg mice), we found that ISF tau is fivefold higher than endogenous murine tau, consistent with its elevated levels of expression. However, following the onset of tau aggregation, monomeric ISF tau decreased markedly. Biochemical analysis demonstrated that soluble tau in brain homogenates decreased along with the deposition of insoluble tau. Tau fibrils injected into the hippocampus decreased ISF tau, suggesting that extracellular tau is in equilibrium with extracellular or intracellular tau aggregates. This technique should facilitate further studies of tau secretion, spread of tau pathology, the effects of different disease states on ISF tau, and the efficacy of experimental treatments.

Neuronal activity regulates extracellular tau in vivo

Neuronal activity promotes the release of extracellular tau in vivo.

Haploinsufficiency of Human APOE Reduces Amyloid Deposition in a Mouse Model of Amyloid-β Amyloidosis

The ε4 allele of the apolipoprotein E (APOE) gene is the strongest genetic risk factor for Alzheimers disease (AD). Evidence suggests that the effect of apoE isoforms on amyloid-β (Aβ) accumulation in the brain plays a critical role in AD pathogenesis. Like in humans, apoE4 expression in animal models that develop Aβ amyloidosis results in greater Aβ and amyloid deposition than with apoE3 expression. However, whether decreasing levels of apoE3 or apoE4 would promote or attenuate Aβ-related pathology has not been directly addressed. To determine the effect of decreasing human apoE levels on Aβ accumulation in vivo, we generated human APOE isoform haploinsufficient mouse models by crossing APPPS1-21 mice with APOE isoform knock-in mice. By genetically manipulating APOE gene dosage, we demonstrate that decreasing human apoE levels, regardless of isoform status, results in significantly decreased amyloid plaque deposition and microglial activation. These differences in amyloid load between apoE3- and apoE4-expressing mice were not due to apoE4 protein being present at lower levels than apoE3. These data suggest that current therapeutic strategies to increase apoE levels without altering its lipidation state may actually worsen Aβ amyloidosis, while increasing apoE degradation or inhibiting its synthesis may be a more effective treatment approach.

Antisense Reduction of Tau in Adult Mice Protects against Seizures

Tau, a microtubule-associated protein, is implicated in the pathogenesis of Alzheimers Disease (AD) in regard to both neurofibrillary tangle formation and neuronal network hyperexcitability. The genetic ablation of tau substantially reduces hyperexcitability in AD mouse lines, induced seizure models, and genetic in vivo models of epilepsy. These data demonstrate that tau is an important regulator of network excitability. However, developmental compensation in the genetic tau knock-out line may account for the protective effect against seizures. To test the efficacy of a tau reducing therapy for disorders with a detrimental hyperexcitability profile in adult animals, we identified antisense oligonucleotides that selectively decrease endogenous tau expression throughout the entire mouse CNS—brain and spinal cord tissue, interstitial fluid, and CSF—while having no effect on baseline motor or cognitive behavior. In two chemically induced seizure models, mice with reduced tau protein had less severe seizures than control mice. Total tau protein levels and seizure severity were highly correlated, such that those mice with the most severe seizures also had the highest levels of tau. Our results demonstrate that endogenous tau is integral for regulating neuronal hyperexcitability in adult animals and suggest that an antisense oligonucleotide reduction of tau could benefit those with epilepsy and perhaps other disorders associated with tau-mediated neuronal hyperexcitability.

Bidirectional relationship between functional connectivity and amyloid-β deposition in mouse brain

Brain region-specific deposition of extracellular amyloid plaques principally composed of aggregated amyloid-β (Aβ) peptide is a pathological signature of Alzheimers disease (AD). Recent human neuroimaging data suggest that resting-state functional connectivity strength is reduced in patients with AD, cognitively normal elderly harboring elevated amyloid burden, and in advanced aging. Interestingly, there exists a striking spatial correlation between functional connectivity strength in cognitively normal adults and the location of Aβ plaque deposition in AD. However, technical limitations have heretofore precluded examination of the relationship between functional connectivity, Aβ deposition, and normal aging in mouse models. Using a novel functional connectivity optical intrinsic signal (fcOIS) imaging technique, we demonstrate that Aβ deposition is associated with significantly reduced bilateral functional connectivity in multiple brain regions of older APP/PS1 transgenic mice. The amount of Aβ deposition in each brain region was associated with the degree of local, age-related bilateral functional connectivity decline. Normal aging was associated with reduced bilateral functional connectivity specifically in retrosplenial cortex. Furthermore, we found that the magnitude of regional bilateral functional correlation in young APP/PS1 mice before Aβ plaque formation was proportional to the amount of region-specific plaque deposition seen later in older APP/PS1 mice. Together, these findings suggest that Aβ deposition and normal aging are associated with region-specific disruption of functional connectivity and that the magnitude of local bilateral functional connectivity predicts regional vulnerability to subsequent Aβ deposition in mouse brain.

Altered microglial response to Aβ plaques in APPPS1-21 mice heterozygous for TREM2.

BackgroundRecent genome-wide association studies linked variants in TREM2 to a strong increase in the odds of developing Alzheimer’s disease. The mechanism by which TREM2 influences the susceptibility to Alzheimer’s disease is currently unknown. TREM2 is expressed by microglia and is thought to regulate phagocytic and inflammatory microglial responses to brain pathology. Given that a single allele of variant TREM2, likely resulting in a loss of function, conferred an increased risk of developing Alzheimer’s disease, we tested whether loss of one functional trem2 allele would affect Aβ plaque deposition or the microglial response to Aβ pathology in APPPS1-21 mice.ResultsThere was no significant difference in Aβ deposition in 3-month old or 7-month old APPPS1-21 mice expressing one or two copies of trem2. However, 3-month old mice with one copy of trem2 exhibited a marked decrease in the number and size of plaque-associated microglia. While there were no statistically significant differences in cytokine levels or markers of microglial activation in 3- or 7-month old animals, there were trends towards decreased expression of NOS2, C1qa, and IL1a in 3-month old TREM2+/− vs. TREM2+/+ mice.ConclusionsLoss of a single copy of trem2 had no effect on Aβ pathology, but altered the morphological phenotype of plaque-associated microglia. These data suggest that TREM2 is important for the microglial response to Aβ deposition but that a 50% decrease inTREM2 expression does not affect Aβ plaque burden.