Partial inhibition of complex I improves bioenergetics via improved glucose uptake/utilization and mitochondrial function in a cellular model of Alzheimer’s disease

Abstract

AbstractBackgroundAlzheimer Disease (AD) currently has no effective treatments. A consistent failure of recent clinical trials focused on Aβ or pTau necessitates the identification of novel therapeutic targets and strategies. Since abnormal brain energy homeostasis and mitochondria dysfunction underlie early stages of AD, the development of treatments to restore these defects could be beneficial. We synthesized small molecules that selectively and mildly inhibit mitochondrial complex I (MCI) which restored synaptic and cognitive function in APP/PS1 and 3xTgAD mice. One of the most important mechanisms improved by the treatment included restoration of glucose uptake/utilization that resulted in augmented cellular energetics in mouse brains. However, mechanistic relationship between MCI inhibition, glucose uptake/utilization and mitochondrial function remains to be determined.MethodNeuroblastoma SH‐SY5Y cells that express mutant human APP protein (APPswe) and WT cells were treated with MCI inhibitors in a time‐ and dose‐dependent manner. Flow cytometry was used to measure the translocation of glucose transporters to the cell surface. Changes in protein expression in response to treatment were assessed using Western blot analysis. Changes in mitochondrial morphology were monitored using electron microscopy. Cellular energetics was assessed using a Seahorse Extracellular Flux Analyzer. The non‐radioactive Glucose Uptake‐Glo™ assay was utilized for measuring glucose uptake in cells.ResultsTreatment of with SH‐SY5Y‐APPswe cells with MCI inhibitors within an hour increased surface translocation of GLUTs enhancing glucose uptake and utilization. The effect persisted for 48 hrs. The mechanism of enhanced glucose uptake was associated with AMPK‐dependent activation of NRF2 pathway but not AKT. Furthermore, the improvement in the bioenergetic parameters including Spare Respiratory Capacity, an indicator of the mitochondrial ability to produce energy under stress conditions, and ATP levels were found 24 hrs after the compound treatment. Treatment activated mitochondrial morphofunctional pathway (e.g., fission, fusion, biogenesis and turnover) consistent with the improved cellular bioenergetics. Similar mechanisms were confirmed in the brain tissue of 3xTgAD mice treated with one of the compounds.ConclusionsPartial MCI inhibition activates multiple mechanisms essential for improved energy homeostasis and mitochondrial function. These mechanisms could be consistently induced by our compounds in vivo and in human brain cells support translational potential of this therapeutic strategy.