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KATP channels are necessary for glucose-dependent increases in amyloid-β and Alzheimer’s disease–related pathology
John Grizzanti, William R. Moritz, Morgan C. Pait, Molly Stanley, Sarah D. Kaye, Caitlin M. Carroll, Nicholas J. Constantino, Lily J. Deitelzweig, James A. Snipes, Derek Kellar, Emily E. Caesar, Ryan J. Pettit-Mee, Stephen M. Day, Jonathon P. Sens, Noelle I. Nicol, Jasmeen Dhillon, Maria S. Remedi, Drew D. Kiraly, Celeste M. Karch, Colin G. Nichols, David M. Holtzman, Shannon L. Macauley
John Grizzanti, William R. Moritz, Morgan C. Pait, Molly Stanley, Sarah D. Kaye, Caitlin M. Carroll, Nicholas J. Constantino, Lily J. Deitelzweig, James A. Snipes, Derek Kellar, Emily E. Caesar, Ryan J. Pettit-Mee, Stephen M. Day, Jonathon P. Sens, Noelle I. Nicol, Jasmeen Dhillon, Maria S. Remedi, Drew D. Kiraly, Celeste M. Karch, Colin G. Nichols, David M. Holtzman, Shannon L. Macauley
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Research Article Aging Neuroscience

KATP channels are necessary for glucose-dependent increases in amyloid-β and Alzheimer’s disease–related pathology

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Abstract

Elevated blood glucose levels, or hyperglycemia, can increase brain excitability and amyloid-β (Aβ) release, offering a mechanistic link between type 2 diabetes and Alzheimer’s disease (AD). Since the cellular mechanisms governing this relationship are poorly understood, we explored whether ATP-sensitive potassium (KATP) channels, which couple changes in energy availability with cellular excitability, play a role in AD pathogenesis. First, we demonstrate that KATP channel subunits Kir6.2/KCNJ11 and SUR1/ABCC8 were expressed on excitatory and inhibitory neurons in the human brain, and cortical expression of KCNJ11 and ABCC8 changed with AD pathology in humans and mice. Next, we explored whether eliminating neuronal KATP channel activity uncoupled the relationship between metabolism, excitability, and Aβ pathology in a potentially novel mouse model of cerebral amyloidosis and neuronal KATP channel ablation (i.e., amyloid precursor protein [APP]/PS1 Kir6.2–/– mouse). Using both acute and chronic paradigms, we demonstrate that Kir6.2-KATP channels are metabolic sensors that regulate hyperglycemia-dependent increases in interstitial fluid levels of Aβ, amyloidogenic processing of APP, and amyloid plaque formation, which may be dependent on lactate release. These studies identify a potentially new role for Kir6.2-KATP channels in AD and suggest that pharmacological manipulation of Kir6.2-KATP channels holds therapeutic promise in reducing Aβ pathology in patients with diabetes or prediabetes.

Authors

John Grizzanti, William R. Moritz, Morgan C. Pait, Molly Stanley, Sarah D. Kaye, Caitlin M. Carroll, Nicholas J. Constantino, Lily J. Deitelzweig, James A. Snipes, Derek Kellar, Emily E. Caesar, Ryan J. Pettit-Mee, Stephen M. Day, Jonathon P. Sens, Noelle I. Nicol, Jasmeen Dhillon, Maria S. Remedi, Drew D. Kiraly, Celeste M. Karch, Colin G. Nichols, David M. Holtzman, Shannon L. Macauley

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Figure 1

KATP channel expression in postmortem humans across the AD continuum.

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KATP channel expression in postmortem humans across the AD continuum.
(A...
(A) KATP channels are heteroctameric, composed of 4 pore-forming subunits (Kir6.2/KCNJ11) and 4 sulfonylurea-binding site (Sur1/ABCC8) subunits. (B) Workflow to explore how KATP channel genes (KCNJ11, ABCC8) in the temporal cortex change because of AD-related pathology using the Mayo RNA-Seq database. (C) KCNJ11 expression trends toward a decrease in AD (amyloid+, tau+), while ABCC8 is significantly reduced in AD in bulk RNA-Seq. (D) Workflow to explore cell type–specific changes in KCNJ11 and ABCC8 expression in postmortem human brains using single-nuclei RNA-Seq (snRNA-Seq) database generated by Mathys et al. (35). (E) KCNJ11 and ABCC8 expression is largely found on excitatory and inhibitory neurons (>96%) but also localized to glia, like oligodendrocyte progenitor cells (OPCs). (F) NC and AD samples were integrated into a single data set and clustered into cell types. Uniform manifold approximation and projection (UMAP) representation of different CNS cell types, including relative expression for KCNJ11 and ABCC8. (G) Gene expression dot blot for KCNJ11 and ABCC8 demonstrating relative expression levels in each cell type. (H) Comparing postmortem brains with no AD pathology (n = 24), early AD pathology (n = 15), and late AD pathology (n = 9), KCNJ11 expression is increased on excitatory neurons with early and late pathology while KCNJ11 expression is increased on inhibitory neurons at a late stage of disease. ABCC8, the binding partner of KCNJ11, is reduced in inhibitory and excitatory neurons across the AD continuum. All data represented as means (statistically analyzed using Student’s t test) ± SEM. *P < 0.05.

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