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dc.contributor.advisorRebeck, G. Williamen
dc.contributor.advisorDzakpasu, Rhondaen
dc.creatoren
dc.date.accessioned2015-06-01T16:37:10Zen
dc.date.available2015-06-01T16:37:10Zen
dc.date.created2015en
dc.date.issueden
dc.date.submitted01/01/2015en
dc.identifier.otherAPT-BAG: georgetown.edu.10822_760910.tar;APT-ETAG: 74fe8488b5374168409bffa33876f9d3; APT-DATE: 2017-02-07_16:24:03en
dc.identifier.urien
dc.descriptionPh.D.en
dc.description.abstractAlzheimer's disease (AD) is a progressive age-related neurodegenerative disorder that results in declarative memory deficits. Apolipoprotein e4 (APOE-ε4) is the strongest genetic risk factor for developing AD, and influences extracellular Aβ plaque deposition and neuroinflammation in humans and in mouse models. APOE-ε4 also influences neuronal morphology and cognitive performance in humans, independent of AD pathology. In this series of experiments, we examined the effects of APOE genotype on AD-related neuropathology and in normal brain function of mice to better understand its role as a potent risk-factor for developing AD.en
dc.description.abstractWe analyzed Aβ plaque profiles and Aβ-induced glial activation in the brains of 6-month old EFAD transgenic mice (E2FAD, E3FAD, and E4FAD). Characterization of Aβ plaques revealed larger and more intensely stained plaques in E4FAD mice relative to E3FADs, and increased numbers of compact plaques in the subiculum. Reactive microglia and astrocytes were prominent in EFAD brains. Morphometric analyses revealed greater dystrophy, increased fluorescence intensity, and a higher density of reactive microglia surrounding cortical plaques in E4FAD mice than in E3FADs. Cortical levels of Interleukin1-β (IL-1β) were nearly two-fold greater in E4FAD mice relative to E3FADs.en
dc.description.abstractTo investigate the impact of APOE genotype on cognitive performance in mice, we trained 3-month old APOE Targeted Replacement mice (APOE2, APOE3, and APOE4) in a spatial learning and memory task (Barnes maze). APOE4 mice exhibited impaired spatial learning and memory in the maze compared to APOE3 mice. Deficits in spatial learning were detected in a second cohort of 18-month old APOE4 mice. When we examined the dendritic morphology of neurons in the medial entorhinal cortex (MEC), we found significantly shorter dendrites and lower spine densities in basal shaft dendrites of APOE4 mice relative to APOE3, consistent with the deficits found in our young APOE4 mice. We also provide evidence to suggest that Liver X Receptor (LXR) activation - which increases APOE - suppresses overall spiking activity and specifically burst counts in mature hippocampal networks recorded in a multielectrode array.en
dc.description.abstractThese data suggest that APOE genotype modulates Aβ-induced neuroinflammatory responses in AD progression, and support a role for APOE in dendritic morphology and normal brain function.en
dc.formatPDFen
dc.format.extent176 leavesen
dc.languageenen
dc.publisherGeorgetown Universityen
dc.sourceGeorgetown University-Graduate School of Arts & Sciencesen
dc.sourceNeuroscienceen
dc.subjectAlzheimer's diseaseen
dc.subjectAPOEen
dc.subjectdendritic spinesen
dc.subjectmedial entorhinal cortexen
dc.subjectmicrogliaen
dc.subjectneuroinflammationen
dc.subject.lcshNeurosciencesen
dc.subject.lcshBiologyen
dc.subject.lcshAgingen
dc.subject.otherNeurosciencesen
dc.subject.otherBiologyen
dc.subject.otherAgingen
dc.titleHuman APOE4 Affects Microglial Reactivity and Spatial Cognition in a Mouse Model of Alzheimer's Disease Risken
dc.typethesisen


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