Alzheimer’s disease (AD) is the most common progressive neurodegenerative disorder causing dementia. Massive deposition of amyloid β peptide (Aβ) as senile plaques in the brain is the pathological hallmark of AD, but oligomeric, soluble forms of Aβ have been implicated as the synaptotoxic component. The apolipoprotein E epsilon 4 (apoE ε4) allele is known to be a genetic risk factor for developing AD. However it is still unknown how apoE impacts the process of Aβ oligomerization. Here, we found that the level of Aβ oligomers in APOEε4/ε4 AD patient brains is 2.7 times higher than those in APOEε3/ε3 AD patient brains, matched for total plaque burden, suggesting that apoE4 impacts the metabolism of Aβ oligomers. To test this hypothesis, we examined apoE’s effect on Aβ oligomer formation. Using both synthetic Aβ and a split-luciferase method for monitoring Aβ oligomers, we observed that apoE increased the level of Aβ oligomers in an isoform dependent manner (E2 < E3 < E4). This effect appears to be dependent on the ApoE carboxy-terminal domain. Moreover, these results were confirmed using endogenous apoE isolated from the TBS-soluble fraction of human brain, which increased the formation of Aβ oligomers. Taken together, these data show that lipidated apoE, especially apoE4, increases Aβ oligomers in the brain. Higher levels of Aβ oligomers in the brains of APOEε4/ε4 carriers compared to APOEε3/ε3 carriers may increase the loss of dendritic spines and accelerate memory impairments, leading to earlier cognitive decline in AD.
Although extensive evidence supports the role of amyloid-β (Aβ) in Alzheimer disease (AD), the neurotoxic mechanisms underlying AD pathogenesis are not understood. On the other hand, neuronal loss is the pathological feature that best correlates with cognitive impairment. We hypothesized that cholinergic neurodegeneration may lead to Aβ deposition and tested this by inducing selective cholinergic lesions in APPswe/PS1dE9 mice with murine p75NTR saporin (mu p75-SAP). Intracerebroventricular lesions that removed ~50% of cholinergic innervation to the cortex and hippocampus were induced in animals with incipient (~3 months) and marked (~7 months of age) Aβ deposition. Cranial windows were implanted and Aβ deposition was monitored in vivo using multiphoton microscopy. Aβ deposition was increased as soon as 7 days after the lesion and this effect was maintained up to 3 months later. Postmortem studies using immunohistochemistry with an anti-Aβ antibody corroborated these findings in both cerebral cortex and hippocampus. Tau phosphorylation was also significantly increased after the lesions. Cholinergic denervation resulted in early memory impairment at 3 months of age that worsened with age (~7 months); there was a synergistic effect between cholinergic denervation and the presence of APP/PS1 transgenes. Altogether, our data suggest that cholinergic denervation may trigger Aβ deposition and synergistically contribute to cognitive impairment in AD patients.
The γ-secretase complex is a major therapeutic target for the prevention and treatment of Alzheimer's disease. Previous studies have shown that treatment of young APP mice with specific inhibitors of γ-secretase prevented formation of new plaques. It has not yet been shown directly whether existing plaques would be affected by γ-secretase inhibitor treatment. Similarly, alterations in neuronal morphology in the immediate vicinity of plaques represent a plaque-specific neurotoxic effect. Reversal of these alterations is an important endpoint of successful therapy whether or not a treatment affects plaque size. In the present study we used longitudinal imaging in vivo with multiphoton microscopy to study the effects of the orally active γ-secretase inhibitor LY-411575 in 10-11 month old APP:PS1 mice with established amyloid pathology and neuritic abnormalities. Neurons expressed YFP allowing fluorescent detection of morphology whereas plaques were labelled with methoxy-XO4. The same identified neurites and plaques were followed in weekly imaging sessions in living mice treated daily (5 mg/kg) for 3 weeks with the compound. Although LY-411575 reduced Aβ levels in plasma and brain, it did not have an effect on the size of existing plaques. There was also no effect on the abnormal neuritic curvature near plaques, or the dystrophies in very close proximity to senile plaques. Our results suggest that therapeutics aimed at inhibition of Aβ generation are less effective for reversal of existing plaques than for prevention of new plaque formation and have no effect on the plaque-mediated neuritic abnormalities, at least under these conditions where Aβ production is suppressed but not completely blocked. Therefore, a combination therapy of Aβ suppression with agents that increase clearance of amyloid and/or prevent neurotoxicity might be needed for a more effective treatment in patients with pre-existing pathology.
Senile plaques, mainly composed of amyloid-β (Aβ), are a major hallmark of Alzheimer disease (AD), and immunotherapy is a leading therapeutic approach for Aβ clearance. Although the ultimate mechanisms for Aβ clearance are not well known, characteristic microglia clusters are observed in the surround of senile plaques, and are implicated both in the elimination of Aβ as well as the deleterious inflammatory effects observed in AD patients after active immunization. Therefore, analyzing the direct effect of immunotherapy on microglia, using longitudinal in vivo multiphoton microscopy can provide important information regarding the role of microglia in immunotherapy. While microglia were observed to surround senile plaques, topical anti-Aβ antibody administration, which led to a reduction in plaque size, directed microglia toward senile plaques, and the overall size of microglia and number of processes were increased. In some cases, we observed clusters of microglia in areas of the brain that did not have detectable amyloid aggregates, but this did not predict the deposition of new plaques in the area within a week of imaging, indicating that microglia react to but do not precipitate amyloid aggregation. The long-term presence of large microglial clusters in the surrounding area of senile plaques suggests that microglia cannot effectively remove Aβ unless anti-Aβ antibody is administered. All together, these data suggest that although there is a role for microglia in Aβ clearance, it requires an intervention like immunotherapy to be effective.
Calcium is a ubiquitous intracellular messenger that has important functions in normal neuronal function. The pathology of Alzheimer's disease has been shown to alter calcium homeostasis in neurons and astrocytes. Several calcium dye indicators are available to measure intracellular calcium within cells, including Oregon Green BAPTA-1 (OGB-1). Using fluorescence lifetime imaging microscopy, we adapted this single wavelength calcium dye into a ratiometric dye to allow quantitative imaging of cellular calcium. We used this approach for in vitro calibrations, single-cell microscopy, high-throughput imaging in automated plate readers, and in single cells in the intact living brain. While OGB is a commonly used fluorescent dye for imaging calcium qualitatively, there are distinct advantages to using a ratiometric approach, which allows quantitative determinations of calcium that are independent of dye concentration. Taking advantage of the distinct lifetime contrast of the calcium-free and calcium-bound forms of OGB, we used time-domain lifetime measurements to generate calibration curves for OGB lifetime ratios as a function of calcium concentration. In summary, we demonstrate approaches using commercially available tools to measure calcium concentrations in live cells at multiple scales using lifetime contrast. These approaches are broadly applicable to other fluorescent readouts that exhibit lifetime contrast and serve as powerful alternatives to spectral or intensity readouts in multiplexing experiments.
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