Mitochondria are key organelles, which maintain energy metabolism and cellular homeostasis. Mitochondria support transcriptional regulation and proteostatic signaling mechanisms through crosstalk between the mitochondria itself, the nucleus, and the cytoplasm. Mitochondrial dysfunction leads to impaired proteostasis, and both are key pathological features of age-related neurological disorders. For example, Alzheimer's and Parkinson's diseases feature mitochondrial-targeted protein aggregates and impaired mitochondrial function, although the mechanistic causes are poorly understood. Vascular abnormalities and hypometabolism in such neurological diseases are reported several years before key clinical disease symptoms even become apparent. Recent investigations suggest that processing of such aggregates within mitochondria can offer protective functions, specifically by restoring energy (ATP) in starving cells. We hypothesize that the accumulation of protein aggregates in mitochondria can not only disrupt its functions, but also render a protective role to fulfill energy demands in hypometabolic conditions. Growing evidence favors mitochondrial defense to toxic amyloid aggregates/oligomers as a protective response. In this viewpoint article, we will present several publications (in addition to our own) that serve to connect the possible role of protein aggregates in mitochondrial energy production for degenerative conditions.
Keywords: ATP energy conversion; Krebs cycle; amyloid protein aggregates; mitochondria; mitochondrial energy homeostasis; mitochondrial processing of amyloid proteins; mitochondrial proteostasis; mitochondrial-associated protein aggregate; neurodegenerative diseases; protein disaggregation by chaperones.
© 2020 Federation of European Biochemical Societies.