Role of the caspase-8/RIPK3 axis in Alzheimer’s disease pathogenesis and Aβ-induced NLRP3 inflammasome activation
Sushanth Kumar, Sakar Budhathoki, Christopher B. Oliveira, August D. Kahle, O. Yipkin Calhan, John R. Lukens, Christopher D. Deppmann
Sushanth Kumar, Sakar Budhathoki, Christopher B. Oliveira, August D. Kahle, O. Yipkin Calhan, John R. Lukens, Christopher D. Deppmann
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Research Article Inflammation Neuroscience

Role of the caspase-8/RIPK3 axis in Alzheimer’s disease pathogenesis and Aβ-induced NLRP3 inflammasome activation

Abstract

The molecular mediators of cell death and inflammation in Alzheimer’s disease (AD) have yet to be fully elucidated. Caspase-8 is a critical regulator of several cell death and inflammatory pathways; however, its role in AD pathogenesis has not yet been examined in detail. In the absence of caspase-8, mice are embryonic lethal due to excessive receptor interacting protein kinase 3–dependent (RIPK3-dependent) necroptosis. Compound RIPK3 and caspase-8 mutants rescue embryonic lethality, which we leveraged to examine the roles of these pathways in an amyloid β–mediated (Aβ-mediated) mouse model of AD. We found that combined deletion of caspase-8 and RIPK3, but not RIPK3 alone, led to diminished Aβ deposition and microgliosis in the mouse model of AD carrying human presenilin 1 and amyloid precursor protein with 5 familial AD mutations (5xFAD). Despite its well-known role in cell death, caspase-8 did not appear to affect cell loss in the 5xFAD model. In contrast, we found that caspase-8 was a critical regulator of Aβ-driven inflammasome gene expression and IL-1β release. Interestingly, loss of RIPK3 had only a modest effect on disease progression, suggesting that inhibition of necroptosis or RIPK3-mediated cytokine pathways is not critical during midstages of Aβ amyloidosis. These findings suggest that therapeutics targeting caspase-8 may represent a novel strategy to limit Aβ amyloidosis and neuroinflammation in AD.

Authors

Sushanth Kumar, Sakar Budhathoki, Christopher B. Oliveira, August D. Kahle, O. Yipkin Calhan, John R. Lukens, Christopher D. Deppmann

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Figure 3

Reduced microgliosis with loss of caspase-8 and RIPK3 in 5xFAD mice.

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Reduced microgliosis with loss of caspase-8 and RIPK3 in 5xFAD mice. (A ...
(A and C) Representative IHC images of the cortex taken at ×40 original magnification (n = 9 5xFAD mice, n = 8 5xFAD Ripk3–/– mice, and n = 6 5xFAD-DKO mice). (A) Iba1 staining. (B) Quantification of Iba1 staining. Each data point is an average of 10 different fields of view taken throughout the cortex spanning 2 different sections per mouse. (C) GFAP staining. (D) Quantification of GFAP staining. Each data point is an average of 10 different fields of view taken throughout the cortex spanning 2 different sections per mouse. (E) Image of cortical Iba1+ microglia (red) surrounding ThioS+ plaque (green) within a 15 μm barrier (yellow) measured from plaque surface taken at ×40 original magnification. (F) Volume of Iba1 staining within the 15 μm barrier was quantified and divided by total barrier volume. (G) Number of microglia as identified by Spots function on Imaris 9.7.2 were counted within the barrier. (F and G) Results from 6–10 plaques were averaged per data point (n = 9 5xFAD mice, n = 9 5xFAD Ripk3–/– mice, and n = 7 5xFAD-DKO mice). (H) Image of microglia (red) costained with CD68 (white) surrounding ThioS+ plaque (green) within a 15 μm barrier (yellow) measured from plaque surface taken at ×40 original magnification. (I) Quantification of cortical microglial CD68 staining within a 15 μm periplaque barrier. Results from 6–10 plaques were averaged per data point. Data were analyzed by 1-way ANOVA followed by Tukey’s post hoc test. All n values refer to the number of mice used, and error bars indicate SEM. Scale bars: 20 μm.