Browsing by Subject "Amyloid accumulation"

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    The effect of amyloid on microglia-neuron interactions before plaque onset occurs independently of TREM2 in a mouse model of Alzheimer’s disease
    (Elsevier, 2020-11) von Saucken, Victoria E.; Jay, Taylor R.; Landreth, Gary E.; Medicine, School of Medicine
    Genetic studies identified mutations in several immune-related genes that confer increased risk for developing Alzheimer's disease (AD), suggesting a key role for microglia in AD pathology. Microglia are recruited to and actively modulate the local toxicity of amyloid plaques in models of AD through these cells' transcriptional and functional reprogramming to a disease-associated phenotype. However, it remains unknown whether microglia actively respond to amyloid accumulation before plaque deposition in AD. We compared microglial interactions with neurons that exhibit amyloid accumulation to those that do not in 1-month-old 5XFAD mice to determine which aspects of microglial morphology and function are altered by early 6E10+ amyloid accumulation. We provide evidence of preferential microglial process engagement of amyloid laden neurons. Microglia, on exposure to amyloid, also increase their internalization of neurites even before plaque onset. Unexpectedly, we found that triggering receptor expressed on myeloid cells 2 (TREM2), which is critical for microglial responses to amyloid plaque pathology later in disease, is not required for enhanced microglial interactions with neurons or neurite internalization early in disease. However, TREM2 was still required for early morphological changes exhibited by microglia. These data demonstrate that microglia sense and respond to amyloid accumulation before plaques form using a distinct mechanism from the TREM2-dependent pathway required later in disease.
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    Tau ablation rescues vascular amyloid‐related deficits in a cerebral amyloid angiopathy model
    (Wiley, 2025-01-03) Mardones, Muriel D.; Jury, Nur; Juarez, Enrique Chimal; Patel, Henika; Martinez, Jonathan; Vanderbosch, Katie; Perkins, Abigail; Marambio, Yamil; Vidal, Ruben; Lasagna Reeves, Cristian A.; Anatomy, Cell Biology and Physiology, School of Medicine
    Background: Close to 80 to 90% of subjects with AD also present cerebral amyloid angiopathy (CAA) a disease in which amyloid accumulation damages the vasculature and impairs blood flow. Since current AD therapies are targeting the disease focusing on amyloid, we are interested on determine how to decrease the accumulation of amyloid in the vasculature observed in CAA and our aim is to determine the impact of tau reduction in CAA pathogenesis. Method: We crossed the Tg‐FDD mice CAA model with Mapt‐/‐ mice to decrease tau levels and analyzed the disease pathogenesis in the different genotypes though behavioral tests, histological and morphometric assays and transcriptomic analysis using the nCounter neuroimmflamation panel from Nanostring. Result: We determined that tau ablation improved motor strength in the Tg‐FDD mice model, reduced amyloid deposition in the vasculature, decrease fibrinogen levels in the cortex, reduced astrocyte branching process associated to immunoreactivity. Nanostring analysis revealed that microglia function, oligodendrocyte and cytokine signaling are altered in the Tg‐FDD mice and that in the Tg‐FDD, Mapt ‐/‐ mice there is an increase in this mechanisms restoring the values to the ones observed in wild type mice. Conclusion: We are currently evaluating the pathways observed in the distinct inflammatory profile in microglia and oligodendrocytes. Our results suggest that tau ablation decreased CAA pathology in the Tg‐FDD mice model, which shows the potential therapeutic implications of targeting tau in CAA and related neurodegenerative diseases.