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Early-life environmental effects on mitochondrial aerobic metabolism: a brood size manipulation in wild great tits.

Nina Cossin-SevrinAntoine StierMikaela HukkanenSandrine ZahnVincent A ViblancKatja AnttilaRuuskanen Suvi
Published in: The Journal of experimental biology (2023)
In avian species, the number of chicks in the nest and subsequent sibling competition for food are major components of the offspring's early-life environment. A large brood size is known to affect chick's growth, leading in some cases to long-lasting effects for the offspring, such as a decrease in size at fledgling and in survival after fledging. An important pathway underlying different growth patterns could be the variation in offspring mitochondrial metabolism through its central role in converting energy. Here, we performed a brood size manipulation in great tits (Parus major) to unravel its impact on offspring's mitochondrial metabolism and reactive oxygen species (ROS) production in red blood cells. We investigated the effects of brood size on chicks' growth and survival, and tested for long-lasting effects on juvenile mitochondrial metabolism and phenotype. As expected, chicks raised in reduced broods had a higher body mass compared to enlarged and control groups. However, mitochondrial metabolism and ROS production were not significantly affected by the treatment either at chick or juvenile stages. Interestingly, chicks raised in very small broods were smaller in size and had higher mitochondrial metabolic rates. The nest of rearing had a significant effect on nestling mitochondrial metabolism. The contribution of the rearing environment in determining offspring mitochondrial metabolism emphasizes the plasticity of mitochondrial metabolism in regards to the nest environment. This study opens new avenues regarding the implication of postnatal environmental conditions in shaping the offspring's early-life mitochondrial metabolism.
Keyphrases
  • early life
  • oxidative stress
  • high fat diet
  • reactive oxygen species
  • dna damage
  • type diabetes
  • red blood cell
  • high resolution
  • skeletal muscle
  • climate change
  • human health
  • atomic force microscopy
  • free survival