Abstract
Mitophagy, the selective removal of damaged mitochondria, is thought to be critical to maintain neuronal homeostasis. Mutations of proteins in the pathway cause neurodegenerative diseases, suggesting defective mitochondrial turnover contributes to neurodegeneration. In primary rat hippocampal neurons, we developed a mitophagy induction paradigm where mild oxidative stress induced low levels of mitochondrial damage. Mitophagy-associated proteins were sequentially recruited to depolarized mitochondria followed by sequestration into autophagosomes. The localization of these mitophagy events had a robust somal bias. In basal and induced conditions, engulfed mitochondria remained in non-acidified organelles for hours to days, illustrating efficient autophagosome sequestration but delayed lysosomal fusion or acidification. Furthermore, expression of an ALS-linked mutation in the pathway disrupted mitochondrial network integrity and this effect was exacerbated by oxidative stress. Thus, age-related decline in neuronal health or expression of disease-associated mutations in the pathway may exacerbate the slow kinetics of neuronal mitophagy, leading to neurodegeneration.
Highlights
The mitochondrial network is a dynamic interconnected system of organelles undergoing continuous renewal and rearrangement to support cellular needs
To quantitatively assess whether these mild oxidative stresses initiated mitochondrial damage, intracellular ROS was detected by a fluorogenic probe, CellROX
While we did note a decrease in the length of axonal mitochondria in both AO-free and Antimycin A (AA) conditions compared to control conditions, we found no significant difference in tetramethyl rhodamine ethyl ester (TMRE) signal per cell (Figure 3—figure supplement 1I–J)
Summary
The mitochondrial network is a dynamic interconnected system of organelles undergoing continuous renewal and rearrangement to support cellular needs. Given that neurons have high-energy demands at sites far from the soma, the targeted delivery and regulated removal of mitochondria are essential at these distal sites (Millecamps and Julien, 2013; Sheng, 2014) These organelles utilize mitochondrial membrane potential to perform cellular functions, including energy generation and Ca2+ buffering. In a second maintenance mechanism, dysfunctional mitochondria are removed through selective mitophagy, where damaged organelles are sequestered and eliminated from the cell, via the autophagic machinery (Harper et al, 2018; Misgeld and Schwarz, 2017; Nguyen et al, 2016; Wang and Klionsky, 2011; Youle and Narendra, 2011) This pathway has been implicated in several neurodegenerative diseases including Parkinson’s disease (PD) and amyotrophic lateral sclerosis (ALS; Evans and Holzbaur, 2019)
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