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Adaptation of the master antioxidant response connects metabolism, lifespan and feather development pathways in birds

Gianni M. Castiglione, Zhenhua Xu, Lingli Zhou, Elia J. Duh

2020Nature Communications55 citationsDOIOpen Access PDF

Abstract

Birds (Aves) display high metabolic rates and oxygen consumption relative to mammals, increasing reactive oxygen species (ROS) formation. Although excess ROS reduces lifespan by causing extensive cellular dysfunction and damage, birds are remarkably long-lived. We address this paradox by identifying the constitutive activation of the NRF2 master antioxidant response in Neoaves (~95% of bird species), providing an adaptive mechanism capable of counterbalancing high ROS levels. We demonstrate that a KEAP1 mutation in the Neoavian ancestor disrupted the repression of NRF2 by KEAP1, leading to constitutive NRF2 activity and decreased oxidative stress in wild Neoaves tissues and cells. Our evidence suggests this ancient mutation induced a compensatory program in NRF2-target genes with functions beyond redox regulation-including feather development-while enabling significant metabolic rate increases that avoid trade-offs with lifespan. The strategy of NRF2 activation sought by intense clinical investigation therefore appears to have also unlocked a massively successful evolutionary trajectory.

Topics & Concepts

Adaptation (eye)KEAP1BiologyFeatherReactive oxygen speciesOxidative stressAntioxidantCell biologyGeneMutationMechanism (biology)Most recent common ancestorPsychological repressionGeneticsEvolutionary biologyEcologyPhylogenetic treeBiochemistryTranscription factorNeuroscienceGene expressionEpistemologyPhilosophyAnimal Behavior and ReproductionPhysiological and biochemical adaptationsNeurobiology and Insect Physiology Research
Adaptation of the master antioxidant response connects metabolism, lifespan and feather development pathways in birds | Litcius