Foxp3 drives oxidative phosphorylation and protection from lipotoxicity
Duncan Howie, … , Alexander G. Betz, Herman Waldmann
Duncan Howie, … , Alexander G. Betz, Herman Waldmann
Published February 9, 2017
Citation Information: JCI Insight. 2017;2(3):e89160. https://doi.org/10.1172/jci.insight.89160.
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Research Article Immunology Metabolism

Foxp3 drives oxidative phosphorylation and protection from lipotoxicity

Abstract

Tregs can adopt a catabolic metabolic program with increased capacity for fatty acid oxidation–fueled oxidative phosphorylation (OXPHOS). It is unclear why this form of metabolism is favored in Tregs and, more specifically, whether this program represents an adaptation to the environment and developmental cues or is “hardwired” by Foxp3. Here we show, using metabolic analysis and an unbiased mass spectroscopy–based proteomics approach, that Foxp3 is both necessary and sufficient to program Treg-increased respiratory capacity and Tregs’ increased ability to utilize fatty acids to fuel oxidative phosphorylation. Foxp3 drives upregulation of components of all the electron transport complexes, increasing their activity and ATP generation by oxidative phosphorylation. Increased fatty acid β-oxidation also results in selective protection of Foxp3+ cells from fatty acid–induced cell death. This observation may provide novel targets for modulating Treg function or selection therapeutically.

Authors

Duncan Howie, Stephen Paul Cobbold, Elizabeth Adams, Annemieke Ten Bokum, Andra Stefania Necula, Wei Zhang, Honglei Huang, David J. Roberts, Benjamin Thomas, Svenja S. Hester, David J. Vaux, Alexander G. Betz, Herman Waldmann

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Figure 3

Respiratory substrate usage by cFoxp3-expressing EL4 T cells.

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Respiratory substrate usage by cFoxp3-expressing EL4 T cells. (A) The el...
(A) The electron transport system with the exogenous experimental substrates added and their contribution to the electron transport highlighted in blue. (B) Increase in oxygen consumption rate induced by palmitate, pyruvate, succinate, and TMPD in digitonin-permeabilized EL4 (white bars) and EL4.cFoxp3 (gray bars) cells. Experiment representative of 3 similar experiments. Means ± SEM. *P < 0.05, **P < 0.01 by Student’s t test. (C and D) Basal (white bars), maximal (black bars), and basal/maximal (red bars) oxygen consumption rate of EL4 (c) and EL4cFoxp3 T cells cultured with 4’HT with the addition of BSA-conjugated palmitate (palm), etomoxir (eto), or BSA-palmitate plus etomoxir. Results representative of 3 separate experiments. Boxes span 25th to 75th percentiles, whiskers represent minimum and maximum values, and horizontal line shows median. *P < 0.05, **P < 0.01, ***P < 0.001 by Student’s t test.