Summary
Classic cardio-metabolic risk factors such as hypertension, stroke, diabetes and hypercholesterolemia all increase the risk of Alzheimer’s disease. We found increased transcription of β-secretase/BACE1, the rate-limiting enzyme for Aβ generation, in eNOS deficient mouse brains and after feeding mice a high fat high cholesterol diet. Up- or down-regulation of PGC-1α reciprocally regulated BACE1 in vitro and in vivo. Modest fasting in mice reduced BACE1 transcription in the brains which was accompanied by elevated PGC-1 expression and activity. Moreover, the suppressive effect of PGC-1 was dependent on activated PPARγ likely via SIRT1-mediated deacetylation in a ligand-independent manner. The BACE1 promoter contains multiple PPAR/RXR sites and direct interactions among SIRT1-PPARγ-PGC-1 at these sites were enhanced with fasting. The novel interference on the BACE1 gene identified here represents a unique non-canonical mechanism of PPARγ-PGC-1 in transcriptional repression in neurons in response to metabolic signals which may involve recruitment of a corepressor NCoR.
Although amyloid beta (Abeta) deposition has been a hallmark of Alzheimer's disease (AD), the absence of a phenotype in the beta amyloid precursor protein (APP) knockout mouse, tends to detract our attention away from the physiological functions of APP. Although much attention has been focused on the neurotoxicity of Abeta, many studies suggest the involvement of APP in neuroplasticity. We found that secreted amyloid precursor protein (sAPP) increased the differentiation of human neural stem cells (hNSCs) in vitro, while an antibody-recognizing APP dose-dependently inhibited these activities. With a high dose of sAPP treatment or wild-type APP gene transfection, hNSCs were differentiated into astrocytes rather than neurons. In vivo, hNSCs transplanted into APP-transgenic mouse brain exhibited glial differentiation rather than neural differentiation. Our results suggest that APP regulates neural stem cell biology in the adult brain, and that altered APP metabolism in Down syndrome or AD may have implications for the pathophysiology of these diseases.
The amyloid precursor protein (APP) has been mainly studied in its role in the production of amyloid β peptides (Aβ), because Aβ deposition is a hallmark of Alzheimer's disease. Although several studies suggest APP has physiological functions, it is still controversial. We previously reported that APP increased glial differentiation of neural progenitor cells (NPCs). In the current study, NPCs transplanted into APP23 transgenic mice primarily differentiated into glial cells.
We have demonstrated that aged animals show significant improvements in cognitive function and neurogenesis after brain transplantation of human neural stem cells or of human adult mesenchymal stem cells that have been dedifferentiated by transfection of the embryonic stem cell gene. We have also demonstrated that peripheral administration of a pyrimidine derivative increased cognition, endogenous brain stem cell proliferation and neurogenesis. These results indicate a bright future for stem cell therapies in Alzheimer's disease (AD). Before this is realized, however, we need to consider the affect of AD pathology on stem cell biology to establish an effective stem cell therapy for this disease. Although amyloid-beta (Abeta) deposition is a hallmark of AD, an absence of a phenotype in the beta-amyloid precursor protein (APP) knockout mouse, might lead one to underestimate the potential physiological functions of APP and suggest that it is unessential or can be compensated for. We have found, however, that APP is needed for differentiation of neural stem cells (NSCs) in vitro, and that NSCs transplanted into a APP-knockout mouse did not migrate or differentiate -- indicating that APP plays an important role in differentiation or migration process of NSCs in the brain. Then again, treatment with high a concentration of APP or its over-expression increased glial differentiation of NSCs. Human NSCs transplanted into APP-transgenic mouse brain exhibited less neurogenesis and active gliosis around the plaque like formations. Treatment of such animals with the compound, (+)-phenserine, that is known to reduce APP protein levels, increased neurogenesis and suppressed gliosis. These results suggest APP levels can regulate NSC biology in the adult brain, that altered APP metabolism in Down syndrome or AD may have implications for the pathophysiology of these diseases, and that a combination of stem cell therapy and regulation of APP levels could provide a treatment strategy for these disorders.
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