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Targeting the Mild-Hypoxia Driving Force for Metabolic and Muscle Transcriptional Reprogramming of Gilthead Sea Bream (Sparus aurata) Juveniles

Fernando Naya-Català, Juan António Martos-Sitcha, Verónica de las Heras, Paula Simó‐Mirabet, Josep À. Calduch-Giner, Jaume Pérez‐Sánchez

2021Biology27 citationsDOIOpen Access PDF

Abstract

saturation) constituted two different groups, depending on if they were fed to visual satiety (control fish) or pair-fed to M-HYP fish. Following the hypoxia conditioning period, all fish were maintained in normoxia and continued to be fed until visual satiation for 3 weeks. The time course of hypoxia-induced changes was assessed by changes in blood metabolic landmarks and muscle transcriptomics before and after exhaustive exercise in a swim tunnel respirometer. In M-HYP fish, our results highlighted a higher contribution of aerobic metabolism to whole energy supply, shifting towards a higher anaerobic fitness following normoxia restoration. Despite these changes in substrate preference, M-HYP fish shared a persistent improvement in swimming performance with a higher critical speed at exercise exhaustion. The machinery of muscle contraction and protein synthesis and breakdown was also largely altered by mild-hypoxia conditioning, contributing this metabolic re-adjustment to the positive regulation of locomotion and to the catch-up growth response during the normoxia recovery period. Altogether, these results reinforce the presence of large phenotypic plasticity in gilthead sea bream, and highlights mild-hypoxia as a promising prophylactic measure to prepare these fish for predictable stressful events.

Topics & Concepts

BiologyRespirometerHypoxia (environmental)Anaerobic exerciseJuvenileRespirometryFish physiologyBioenergeticsPhenotypic plasticityAnimal scienceEcologyAnatomyFisheryOxygenFish <Actinopterygii>PhysiologyBiochemistryRespirationChemistryOrganic chemistryMitochondrionPhysiological and biochemical adaptationsHigh Altitude and HypoxiaAquaculture Nutrition and Growth