Respiratory plasticity during acclimation to hypoxia and following a recovery in normoxia

Abstract: Phenotypic plasticity manifested after acclimatization is a very important source of biological variability among fish species. We hypothesized that hypoxic acclimation, besides potentially generating a temporary hypoxic respiratory phenotype, would also manifest as a continued benefit after re-acclimation to normoxia. Hence, we holistically characterized the respiratory phenotype of European sea bass (Dicentrarchus labrax) acclimated to normoxia with or without prior acclimation to hypoxia. Compared with the … Show more

“…The EPOC is an integral area of Ṁ O 2 measured during post-exercise recovery, from the end of U crit until reached Ṁ O 2rest plus 10% [ 36 ]. This approach reduces the likelihood of overestimating EPOC due to spontaneous activities [ 36 ] while taking into account a conceptual framework to estimate the anaerobic costs for activities [ 71 – 74 ]. To account for the allometric scaling effect, we used the total amount of O 2 consumed (mg O 2 ) by the standardized body mass of fish (1.66 g) for fish schools and solitary fish.…”

Collective movement of schooling fish reduces the costs of locomotion in turbulent conditions

“…The EPOC is an integral area of Ṁ O 2 measured during post-exercise recovery, from the end of U crit until reached Ṁ O 2rest plus 10% [ 36 ]. This approach reduces the likelihood of overestimating EPOC due to spontaneous activities [ 36 ] while taking into account a conceptual framework to estimate the anaerobic costs for activities [ 71 – 74 ]. To account for the allometric scaling effect, we used the total amount of O 2 consumed (mg O 2 ) by the standardized body mass of fish (1.66 g) for fish schools and solitary fish.…”

Collective movement of schooling fish reduces the costs of locomotion in turbulent conditions