The adaptive antioxidant response during fasting-induced muscle atrophy is oppositely regulated by ZEB1 and ZEB2.
Chiara NinfaliMarlies CortésM C Martínez-CampanarioVerónica DomínguezLu HanEster TobíasAnna Esteve-CodinaCarlos EnrichBelén PintadoGloria GarrabouAntonio PostigoPublished in: Proceedings of the National Academy of Sciences of the United States of America (2023)
Reactive oxygen species (ROS) serve important homeostatic functions but must be constantly neutralized by an adaptive antioxidant response to prevent supraphysiological levels of ROS from causing oxidative damage to cellular components. Here, we report that the cellular plasticity transcription factors ZEB1 and ZEB2 modulate in opposing directions the adaptive antioxidant response to fasting in skeletal muscle. Using transgenic mice in which Zeb1 or Zeb2 were specifically deleted in skeletal myofibers, we show that in fasted mice, the deletion of Zeb1 , but not Zeb2 , increased ROS production and that the adaptive antioxidant response to fasting essentially requires ZEB1 and is inhibited by ZEB2. ZEB1 expression increased in fasted muscles and protected them from atrophy; conversely, ZEB2 expression in muscles decreased during fasting and exacerbated muscle atrophy. In fasted muscles, ZEB1 reduces mitochondrial damage and increases mitochondrial respiratory activity; meanwhile, ZEB2 did the opposite. Treatment of fasting mice with Zeb1 -deficient myofibers with the antioxidant triterpenoid 1[2-cyano-3,12-dioxool-eana-1,9(11)-dien-28-oyl] trifluoro-ethylamide (CDDO-TFEA) completely reversed their altered phenotype to that observed in fasted control mice. These results set ZEB factors as potential therapeutic targets to modulate the adaptive antioxidant response in physiopathological conditions and diseases caused by redox imbalance.
Keyphrases
- epithelial mesenchymal transition
- long non coding rna
- oxidative stress
- poor prognosis
- skeletal muscle
- reactive oxygen species
- insulin resistance
- cell death
- signaling pathway
- blood glucose
- anti inflammatory
- dna damage
- type diabetes
- adipose tissue
- endothelial cells
- binding protein
- dna binding
- wild type
- human health
- stress induced
- smoking cessation
- replacement therapy