Development of Novel Partial Mitochondrial Complex I Inhibitors as a Therapy for Alzheimer Disease.

Abstract

AbstractBackgroundConsistent failure of clinical trials for Alzheimer Disease (AD) emphasizes the necessity to identify novel therapeutic targets for this debilitating condition. We recently identified the mitochondrial complex I (MCI) as a small molecule druggable therapeutic target for AD.MethodUsing rational design and extensive structure‐activity relationship studies, we developed novel classes of partial MCI inhibitors with high selectivity, specificity, safety, and drug‐like properties. Target engagement, selectivity and specificity of new compounds were established using multiple in vitro assays, including surface plasmon resonance (SPR), competitive and direct binding, proteomics and pull down experiments. Using these techniques, we developed new lead compound C458 that was interrogated in in vivo efficacy studies in APP/PS1 mice.ResultWe demonstrated that the new lead C458 directly binds to MCI. A single dose administration of C458 to mice or treatment of primary mouse neurons activates AMPK‐a, Akt, autophagy, Sirtuins 1 and 3, and upregulates PGC‐1a leading to enhanced mitochondrial biogenesis. C458 has excellent oral bioavailability, blood–brain‐barrier penetrance, and was remarkably clean in the 250 kinase and CEREP 44 safety panels. Chronic administration of C458 (25 mg/kg/day in drinking water ad lib) to APP/PS1 mice for 6 months starting at pre‐symptomatic stage did not cause detectable side effects, and resulted in cognitive protection, improved long‐term potentiation, and decreased oxidative stress and inflammation. Furthermore, APP/PS1 mice treated with C458 showed a significant increase in glucose uptake and utilization in the brain detected with a translational in vivo biomarker FDG‐PET, as well as an enhancement of ATP production measured in vivo using 31P NMR.ConclusionMechanistic studies confirmed that C458 treatment triggered mitochondrial stress response augmenting mitochondrial biogenesis, anti‐oxidant signaling, and cellular energetics that ultimately restored energy brain homeostasis, leading to cognitive protection in a mouse model of AD. Our studies demonstrate that modulation of MCI activity using novel specific MCI inhibitors improves bioenergetics in the brain and averts cognitive decline representing novel therapeutic approach for AD.