Investigating the role of mitochondrial calcium uniporter beta in Alzheimer’s disease

Abstract

AbstractBackgroundWe have recently shown that mitochondrial calcium (mCa2+) overload significantly contributes to the development of Alzheimer’s disease (AD). We found that either genetic inhibition of the neuronal mitochondrial calcium uniporter (MCU, the primary route for mCa2+ influx)1 or enhancement of mitochondrial Na+/Ca2+ exchanger (NCLX, the primary route for mCa2+ efflux)2 in the AD mouse model reduces AD‐associated phenotype and mitochondrial permeability transition pore (MPTP)‐induced cell death. However, blocking either the mCa2+ influx or enhancing mCa2+ efflux can also shut down the bioenergetics. Thus, it is vital to find a regulator of mCa2+ homeostasis that will positively impact Ca2+‐dependent physiological functions.MethodsTo define the new molecular regulatory mechanism to limit mCa2+ overload in AD that will maintain bioenergetics and prevent cell death, we have examined the role of Mitochondrial Calcium Uniporter Beta (MCUB), a paralog of MCU that acts as a negative regulator of mCa2+ uptake3. This study used AD patient samples, mice, and cell lines to examine MCUB expression. A neuroblastoma cell line stably expressing the human Swedish mutant amyloid precursor protein (N2a/APPswe) with adenovirus encoding MCUB was examined for mitochondrial alterations in: Ca2+ handling, ROS generation, permeability transition pore activation, oxidative phosphorylation (OxPHOS) and cell death.Results5xFAD mice and human AD brain samples displayed significant reductions in the expression of MCUB. Studies performed in N2a/APPswe neurons discovered that mCa2 handling, redox, and bioenergetics was severely impaired in AD cells. Rescue of MCUB via adenoviral expression enhanced the clearance of pathogenic mCa2+, enhanced OxPHOS, and prevented ROS and cell death.ConclusionsOur data suggest that MCUB modulation has the therapeutic potential to preserve bioenergetics and limit cell death in AD. This project will further utilize neuronal‐specific knockouts and overexpression of MCUB to increase or decrease mCa2+ uptake, respectively, in 5xFAD mouse models and will explore whether and how MCUB‐mediated changes in uptake are able to preserve metabolism, mCa2+ dynamics, and AD‐phenotype in vivo.