SUMMARY Precise regulation of cellular metabolism is hypothesized to constitute a vital component of the developmental sequence underlying the life-long generation of hippocampal neurons from quiescent neural stem cells (NSCs). The identity of stage-specific metabolic programs and their impact on adult neurogenesis are largely unknown. We show that the adult hippocampal neurogenic lineage is critically dependent on the mitochondrial electron transport chain and oxidative phosphorylation machinery at the stage of the fast proliferating intermediate progenitor cell. Perturbation of mitochondrial complex function by ablation of the mitochondrial transcription factor A (Tfam) reproduces multiple hallmarks of aging in hippocampal neurogenesis, whereas pharmacological enhancement of mitochondrial function ameliorates age-associated neurogenesis defects. Together with the finding of age-associated alterations in mitochondrial function and morphology in NSCs, these data link mitochondrial complex function to efficient lineage progression of adult NSCs and identify mitochondrial function as a potential target to ameliorate neurogenesis-defects in the aging hippocampus.
Aberrant neuronal network activity associated with neuronal hyperexcitability seems to be an important cause of cognitive decline in aging and Alzheimer's disease (AD). Out of many antiepileptics, only levetiracetam improved cognitive dysfunction in AD patients and AD animal models by reducing hyperexcitability. As impaired inhibitory interneuronal function, rather than overactive neurons, seems to be the underlying cause, improving impaired neuronal function rather than quieting overactive neurons might be relevant in explaining the lack of activity of the other antiepileptics. Interestingly, improvement of cognitive deficits by levetiracetam caused by small levels of soluble Aβ was accompanied by improvement of synaptic function and plasticity. As the negative effects of Aβ on synaptic plasticity strongly correlate with mitochondrial dysfunction, wehypothesized that the effect of levetiracetam on synaptic activity might be raised by an improved mitochondrial function. Accordingly, we investigated possible effects of levetiracetam on neuronal deficits associated with mitochondrial dysfunction linked to aging and AD. Levetiracetam improved several aspects of mitochondrial dysfunction including alterations of fission and fusion balance in a cell model for aging and early late-onset AD. We demonstrate for the first time, using immunohistochemistry and proteomics, that the synaptic vesicle protein 2A (SV2a), the molecular target of levetiracetam, is expressed in mitochondria. In addition, levetiracetam shows significant effect on the opening of the mitochondrial permeability transition pore. Importantly, the effects of levetiracetam were significantly abolished when SV2a was knockdown using siRNA. In conclusion, interfering with the SV2a protein at the mitochondrial level and thereby improving mitochondrial function might represent an additional therapeutic effect of levetiracetam to improve symptoms of late-onset AD.
Recent data suggest that the combined effect of oxidative stress due to aging and slightly elevated amyloid-β (Aβ) levels initiate Alzheimer's disease (AD) long before the clinical onset. Investigations of this early phase are hampered by the lack of cellular or animal models reflecting this scenario. We used SH-SY5Y cells stably transfected with an additional copy of the human AβPP gene and artificial aging by complex I inhibition. These cells show slightly elevated Aβ levels, moderately decreased ATP levels, impaired mitochondrial membrane potential, and decreased mitochondrial respiration. Assessing mitochondrial dynamics with three different methods reveals a distinct shift toward mitochondrial fission and fragmentation in SH-SY5Y AβPPwt cells. We also performed electron cryo-tomography of isolated mitochondria to reveal that there were no major differences between SH-SY5Y control and SH-SY5Y AβPPwt mitochondria with respect to swelling or loss of cristae. Dystrophic neurites are an early pathological feature of AD. Interestingly, SH-SY5Y AβPPwt cells exhibit significantly longer neurites, likely due to substantially elevated levels of sAβPPα. Complex I inhibition also shows substantial effects on mitochondrial dynamics, impairs neuritogenesis, and elevates Aβ levels in both cell types. In SH-SY5Y AβPPwt cells, these defects were more pronounced due to a relatively elevated Aβ and a reduced sAβPPα production. Our findings suggest that the progression from low Aβ levels to the beginning of AD takes place in the presence of oxidative stress during normal aging. This mechanism not only results from additive effects of both mechanisms on mitochondrial function but might also be additionally aggravated by altered amyloidogenic processing.
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