TNFα Exposure Decreases Mitochondrial O 2 Consumption in Motor Neurons

Neuroinflammation triggers a homeostatic response that is mediated by pro‐inflammatory cytokines such as TNFα. We hypothesize that in a motor neuron‐like cell line, NSC‐34, TNFα decreases mitochondrial O 2 consumption. NSC‐34 cells were differentiated by serum depletion (~24 h) until neurite structures (>50 μm) were observed. The cells were then exposed to TNFα (20 ng/ml) for 24 h. To determine mitochondrial volume density, the cells were loaded with MitoTracker Green and imaged in 3D using a Nikon A1R confocal microscope (60x oil immersion 1.4 NA). After treatment with TNFα, mitochondria appeared fragmented but mitochondrial volume density increased by ~50%, as compared to control untreated cells. A Agilent Seahorse XF Analyzer was used to determine the O 2 consumption of treated and untreated cells during a stress test that determines basal respiration, ATP production and maximum respiration. O 2 consumption was normalized to mitochondrial volume density in both treated and untreated groups. After TNFα exposure, basal respiration, ATP production and maximum respiration decreased per mitochondrion. However, overall O 2 consumption of the cells was unchanged after TNFα exposure due to an offsetting increase in mitochondrial volume density. Using MitoSox, we also measured reactive oxygen species (ROS) formation in treated and untreated NSC‐34 cells. ROS is a byproduct of mitochondrial O 2 consumption, and can cause cellular damage. After TNFα exposure, ROS formation increased compared to untreated cells. We conclude that mitochondrial biogenesis and an increase in mitochondrial volume density represent a homeostatic mechanism to reduce O 2 consumption the per mitochondrion, thereby damping ROS formation while maintaining overall cellular O 2 consumption and ATP production. Support or Funding Information Supported by NIH grant AG44615 and HL105355.