Molecular Metabolism (Jul 2022)

Loss of UCP1 function augments recruitment of futile lipid cycling for thermogenesis in murine brown fat

  • Josef Oeckl,
  • Petra Janovska,
  • Katerina Adamcova,
  • Kristina Bardova,
  • Sarah Brunner,
  • Sebastian Dieckmann,
  • Josef Ecker,
  • Tobias Fromme,
  • Jiri Funda,
  • Thomas Gantert,
  • Piero Giansanti,
  • Maria Soledad Hidrobo,
  • Ondrej Kuda,
  • Bernhard Kuster,
  • Yongguo Li,
  • Radek Pohl,
  • Sabine Schmitt,
  • Sabine Schweizer,
  • Hans Zischka,
  • Petr Zouhar,
  • Jan Kopecky,
  • Martin Klingenspor

Journal volume & issue
Vol. 61
p. 101499

Abstract

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Objective: Classical ATP-independent non-shivering thermogenesis enabled by uncoupling protein 1 (UCP1) in brown adipose tissue (BAT) is activated, but not essential for survival, in the cold. It has long been suspected that futile ATP-consuming substrate cycles also contribute to thermogenesis and can partially compensate for the genetic ablation of UCP1 in mouse models. Futile ATP-dependent thermogenesis could thereby enable survival in the cold even when brown fat is less abundant or missing. Methods: In this study, we explore different potential sources of UCP1-independent thermogenesis and identify a futile ATP-consuming triglyceride/fatty acid cycle as the main contributor to cellular heat production in brown adipocytes lacking UCP1. We uncover the mechanism on a molecular level and pinpoint the key enzymes involved using pharmacological and genetic interference. Results: ATGL is the most important lipase in terms of releasing fatty acids from lipid droplets, while DGAT1 accounts for the majority of fatty acid re-esterification in UCP1-ablated brown adipocytes. Furthermore, we demonstrate that chronic cold exposure causes a pronounced remodeling of adipose tissues and leads to the recruitment of lipid cycling capacity specifically in BAT of UCP1-knockout mice, possibly fueled by fatty acids from white fat. Quantification of triglyceride/fatty acid cycling clearly shows that UCP1-ablated animals significantly increase turnover rates at room temperature and below. Conclusion: Our results suggest an important role for futile lipid cycling in adaptive thermogenesis and total energy expenditure.

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