Impaired
or deficient autophagy is believed to cause or contribute to aging, as well
as a number of age-related pathologies. The exact mechanism through which
alterations in autophagy induce these various pathologies is not well
understood. Here we describe the creation of two in vivo mouse
models that allow for the characterization of the alteration in
mitochondrial function and the contribution of the corresponding oxidative
stress following deletion of Atg7. Using these models we demonstrate that
isolated mitochondria obtained from Atg7-/- skeletal muscle
exhibit a significant defect in mitochondrial respiration. We further show
that cells derived from Atg7-/- mice have an altered metabolic
profile characterized by decreased resting mitochondrial oxygen consumption
and a compensatory increase in basal glycolytic rates. Atg7-/-cells
also exhibit evidence for increased steady state levels of reactive oxygen
species. The observed mitochondrial dysfunction and oxidative stress is
also evident in a mouse model where Atg7 is deleted within the pancreatic
β cell. In this model, the simple administration of an antioxidant can
significantly ameliorate the physiological impairment in glucose-stimulated
insulin secretion. Taken together, these results demonstrate the potential
role of mitochondrial dysfunction and oxidative stress in autophagy related
pathology.
The amyloid-β (Aβ) peptides are key molecules in Alzheimer's disease (AD) pathology. They interact with cellular membranes, and can bind metal ions outside the membrane. Certain oligomeric Aβ aggregates are known to induce membrane perturbations and the structure of these oligomers-and their membrane-perturbing effects-can be modulated by metal ion binding. If the bound metal ions are redox active, as e.g., Cu and Fe ions are, they will generate harmful reactive oxygen species (ROS) just outside the membrane surface. Thus, the membrane damage incurred by toxic Aβ oligomers is likely aggravated when redox-active metal ions are present. The combined interactions between Aβ oligomers, metal ions, and biomembranes may be responsible for at least some of the neuronal death in AD patients.
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