P4‐165: 3xTg‐AD mouse neurons show early oxidized redox state

factor levels, respectively. Neurons were pre-treated for 2 days with estrogen at the low concentration of 10 pg/mL. Results: In our aging model of rat cortical neurons in common culture conditions, mitochondrial counts per neuron were found to be the same in middle-age (9-month) and old (24-month) neurons. Immunostaining for cytochrome C in individual mitochondria revealed an age-related deficit of this electron donor. Respiration measurements in middle-age and old neurons revealed no age-related changes in basal respiration, but after a glutamate stimulus, old neurons were unable to match the two-fold upregulation of respiration seen in middle-age neurons. Respiration in old neurons was inhibited by lower concentrations of potassium cyanide, suggesting a 29% deficit in functional enzyme in old compared to middle-age neurons. CCO activity in submitochondrial particles isolated from middle-age and old rat cortical neurons in culture showed no age-related differences. In addition to cytochrome C, CCO requires cardiolipin to function. Staining with nonylacridine orange revealed an age-related deficit in cardiolipin. Estrogen treatment of old neurons restored cardiolipin levels and upregulated respiration under glutamate stress. Attempts to induce mitochondrial turnover by neuronal multiplication also rejuvenated CCO activity in old neurons. Conclusions: These data suggest cytochrome C and cardiolipin levels are deficient in old neurons, preventing normal upregulation of respiration needed for oxidative phosphorylation in response to stress. Furthermore, the data suggest this deficit can be corrected with estrogen. These results provide a better understanding of the brain metabolic deficiencies that occur with age, possibly leading to susceptibility to Alzheimer’s Disease.