Consequences of mitochondrial DNA depletion in microglial cells

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AbstractBackgroundMitochondrial dysfunction is an early and prominent feature of Alzheimer’s disease (AD). We have recently published that lower brain mitochondrial DNA copy number (mtDNAcn) is associated with a greater odds of AD neuropathological change and worse cognitive performance. As it is known that microglial cells play an important role in AD, we want to address how a reduction in mtDNAcn may affect microglial function.Methodsmicroglial BV2 cells were treated with ethidium bromide (etbr) (1ug/ml) for 5 days to achieve a 95% reduction of mitochondrial‐encoded genes expression. Cells were characterized by RNAseq and Seahorse experiments. BV2 cells were challenged with latex beads and 10uM zymosan‐pHrodo for 24 hours and phagocytosis was analyzed by flow cytometry. BV2 cells were stimulated with LPS (100ng/ml) for 3 hours to measure cytokine release by qPCR and ELISA. After BV2 stimulation, fresh media (without LPS or etbr) was conditioned for 6 hours and collected to treat neurons (SH‐SY5Y cells) and human primary astrocytes for 24 hours. RNA and protein samples were collected.ResultsmtDNAcn reduction led to a dramatic reduction in oxidative phosphorylation and a mild reduction in proliferation. RNAseq data showed an increase in the hypoxia signature and cellular senescence, coupled with a reduction in biosynthetic process and response to interferon. No changes were observed in phagocytic capacity. However, after LPS stimulation, etbr‐treated cells showed a reduction in the production of IL1B and IL6 cytokines, suggesting an impairment in the response to challenge. Neurons exposed to media from etbr‐treated BV2 cells showed an increase in MAPT and APOE expression. Samples from astrocytes are currently being analyzed.ConclusionsmtDNAcn reduction impairs mitochondrial respiration, which affects the production of cytokines in response to stimulus and leads to cell senescence in microglial cells. Cytokines released by microglia affected neuronal expression of AD‐related genes.